Abstract: A field effect transistor includes: a channel layer 103 containing GaN or InGaN; a first electron-supplying layer 104 disposed over the channel layer 103 and containing InxAlyGa1-x-yN (0?x<1, 0<y<1, 0<x+y<1); a first etch stop layer 105 disposed over the first electron-supplying layer 104 and containing indium aluminum nitride (InAlN); and a second electron-supplying layer 106 provided over the first etch stop layer 105 and containing InaAlbGa1-a-bN (0?a<1, 0<b<1, 0<a+b<1). A first recess 111, which extends through the second electron-supplying layer 106 and the first etch stop layer 105 and having a bottom surface constituted of a section of the first electron-supplying layer 104, is provided in the second electron-supplying layer 106 and the first etch stop layer 105. A gate electrode 109 covers the bottom surface of the first recess 111 and is disposed in the first recess 111.

Abstract: Planar Schottky diodes for which the semiconductor material includes a heterojunction which induces a 2DEG in at least one of the semiconductor layers. A metal anode contact is on top of the upper semiconductor layer and forms a Schottky contact with that layer. A metal cathode contact is connected to the 2DEG, forming an ohmic contact with the layer containing the 2DEG.

Abstract: According to example embodiments, a semiconductor device may include a high electron mobility transistor (HEMT) on a first region of a substrate, and a diode on a second region of the substrate. The HEMT may be electrically connected to the diode. The HEMT and the diode may be formed on an upper surface of the substrate such as to be spaced apart from each other in a horizontal direction. The HEMT may include a semiconductor layer. The diode may be formed on another portion of the substrate on which the semiconductor layer is not formed. The HEMT and the diode may be cascode-connected to each other.

Abstract: A III-nitride semiconductor electronic device comprises a semiconductor laminate provided on a primary surface of a substrate, a first electrode in contact with the semiconductor laminate, and a second electrode. The semiconductor laminate includes a channel layer and a barrier layer making a junction with the channel layer. The channel layer comprises first III-nitride semiconductor containing aluminum as a Group III constituent element, and the barrier layer comprises second III-nitride semiconductor containing aluminum as a Group III constituent element. The semiconductor laminate including first, second and third regions arranged along the primary surface, and the third region is located between the first region and the second region. The barrier layer includes first to third portions included in the first to third regions, respectively.

Abstract: An improved structure of the high electron mobility transistor (HEMT) and a fabrication method thereof are disclosed. The improved HEMT structure comprises a substrate, a channel layer, a spacing layer, a carrier supply layer, a Schottky layer, a first etch stop layer, a first n type doped layer formed by AlxGa1-xAs, and a second n type doped layer. The fabrication method comprises steps of: etching a gate, a drain, and a source recess by using a multiple selective etching process. Below the gate, the drain, and the source recess is the Schottky layer. A gate electrode is deposited in the gate recess to form Schottky contact. A drain electrode and a source electrode are deposited to form ohmic contacts in the drain recess and the source recess respectively, and on the second n type doped layer surrounding the drain recess and the source recess respectively.

Abstract: An electronic component includes a high-voltage depletion-mode transistor and a low-voltage enhancement-mode transistor both encased in a single package. A source electrode of the high-voltage depletion-mode transistor is electrically connected to a drain electrode of the low-voltage enhancement-mode transistor, a drain electrode of the high-voltage depletion-mode transistor is electrically connected to a drain lead of the single package, a gate electrode of the low-voltage enhancement-mode transistor is electrically connected to a gate lead of the single package, a gate electrode of the high-voltage depletion-mode transistor is electrically connected to an additional lead of the single package, and a source electrode of the low-voltage enhancement-mode transistor is electrically connected to a conductive structural portion of the single package.

Abstract: According to one embodiment, a semiconductor device has a first nitride semiconductor layer, a second nitride semiconductor layer provided on the first nitride semiconductor layer and formed of a non-doped or n-type nitride semiconductor having a band gap wider than that of the first nitride semiconductor layer, a heterojunction field effect transistor having a source electrode, a drain electrode, and a gate electrode, a Schottky barrier diode having an anode electrode and a cathode electrode, and first and second element isolation insulating layers. The first element isolation insulating layer has a first end contacting with the drain electrode and the anode electrode, and a second end located in the first nitride semiconductor layer. The second element isolation insulating layer has a third end contacting with the cathode electrode, and a fourth end located in the first nitride semiconductor layer.

Abstract: An AlN layer (2), a GaN buffer layer (3), a non-doped AlGaN layer (4a), an n-type AlGaN layer (4b), an n-type GaN layer (5), a non-doped AlN layer (6) and an SiN layer (7) are sequentially formed on an SiC substrate (1). At least three openings are formed in the non-doped AlN layer (6) and the SiN layer (7), and a source electrode (8a), a drain electrode (8b) and a gate electrode (19) are evaporated in these openings.

Abstract: A nitride-based semiconductor diode includes a substrate, a first semiconductor layer disposed on the substrate, and a second semiconductor layer disposed on the first semiconductor layer. The first and second semiconductor layers include a nitride-based semiconductor. A first portion of the second semiconductor layer may have a thickness thinner than a second portion of the second semiconductor layer. The diode may further include an insulating layer disposed on the second semiconductor layer, a first electrode covering the first portion of the second semiconductor layer and forming an ohmic contact with the first semiconductor layer and the second semiconductor layer, and a second electrode separated from the first electrode, the second electrode forming an ohmic contact with the first semiconductor layer and the second semiconductor layer.

Abstract: Enhancement mode III-nitride devices are described. The 2DEG is depleted in the gate region so that the device is unable to conduct current when no bias is applied at the gate. Both gallium face and nitride face devices formed as enhancement mode devices.

Abstract: Provided are a variable field effect transistor (FET) designed to suppress a reduction of current between a source and a drain due to heat while decreasing a temperature of the FET, and an electrical and electronic apparatus including the variable gate FET. The variable gate FET includes a FET and a gate control device that is attached to a surface or a heat-generating portion of the FET and is connected to a gate terminal of the FET so as to vary a voltage of the gate terminal. A channel current between the source and drain is controlled by the gate control device that varies the voltage of the gate terminal when the temperature of the FET increases above a predetermined temperature.

Abstract: A transistor device includes a high electron mobility field effect transistor (HEMT) and a protection device. The HEMT has a source, a drain and a gate. The HEMT switches on and conducts current from the source to the drain when a voltage applied to the gate exceeds a threshold voltage of the HEMT. The protection device is monolithically integrated with the HEMT so that the protection device shares the source and the drain with the HEMT and further includes a gate electrically connected to the source. The protection device conducts current from the drain to the source when the HEMT is switched off and a reverse voltage between the source and the drain exceeds a threshold voltage of the protection device. The protection device has a lower threshold voltage than the difference of the threshold voltage of the HEMT and a gate voltage used to turn off the HEMT.

Abstract: According to one embodiment, a nitride semiconductor device has an electroconductive substrate, a first nitride semiconductor layer provided directly on the electroconductive substrate or provided on the electroconductive substrate through a buffer layer and formed of a non-doped nitride semiconductor, a second nitride semiconductor layer provided on the first nitride semiconductor layer and formed of a non-doped or n-type nitride semiconductor having a band gap wider than that of the first nitride semiconductor layer, a heterojunction field effect transistor having a source electrode, a drain electrode, and a gate electrode, a Schottky barrier diode having an anode electrode and a cathode electrode, first and second element isolation insulating layers, and a frame electrode. The frame electrode is electrically connected to the source electrode and the electroconductive substrate, and surrounds outer peripheries of the heterojunction field effect transistor and the Schottky barrier diode.

Abstract: A semiconductor device includes a compound semiconductor substrate; a first conductivity type-channel field-effect transistor region formed on the compound semiconductor substrate, and that includes a first channel layer; a first conductivity type first barrier layer that forms a heterojunction with the first channel layer, and supplies a first conductivity type charge to the first channel layer; and a second conductivity type gate region that has a pn junction-type potential barrier against the first conductivity type first barrier layer; and a second conductivity type-channel field-effect transistor region formed on the compound semiconductor substrate, and that includes a second conductivity type second channel layer, and a first conductivity type gate region that has a pn junction-type potential barrier against the second conductivity type second channel layer.

Abstract: According to one disclosed embodiment, a monolithic vertically integrated composite device comprises a double sided semiconductor substrate having first and second sides, a group IV semiconductor layer formed over the first side and comprising at least one group IV semiconductor device, and a group III-V semiconductor body formed over the second side and comprising at least one group III-V semiconductor device electrically coupled to the at least one group IV semiconductor device. The composite device may further comprise a substrate via and/or a through-wafer via providing electric coupling. In one embodiment, the group IV semiconductor layer may comprise an epitaxial silicon layer, and the at least one group IV semiconductor device may be a combined FET and Schottky diode (FETKY) fabricated on the epitaxial silicon layer. In one embodiment, the at least one group III-V semiconductor device may be a III-nitride high electron mobility transistor (HEMT).

Abstract: The present invention provides a semiconductor structure with a hybrid of Ge and a group III-V material coplanar and a preparation method thereof. A heterogeneously integrated semiconductor structure with Ge and a group III-V semiconductor material coplanar includes at least one Ge substrate formed on a bulk silicon substrate, and the other substrate is the group III-V semiconductor material formed on the Ge semiconductor.

Abstract: Some exemplary embodiments of high voltage cascoded III-nitride semiconductor package utilizing clips on a package support surface have been disclosed. One exemplary embodiment comprises a III-nitride transistor attached to a package support surface and having an anode of a diode stacked over a source of the III-nitride transistor, a first conductive clip coupled to a gate of the III-nitride transistor and the anode of the diode, and a second conductive clip coupled to a drain of the III-nitride transistor. The conductive clips are connected to the package support surface and expose respective flat portions that are surface mountable. In this manner, reduced package footprint, improved surge current capability, and higher performance may be achieved compared to conventional wire bonded packages. Furthermore, since a low cost printed circuit board (PCB) may be utilized for the package support surface, expensive leadless fabrication processes may be avoided for cost effective manufacturing.

Abstract: In one implementation, a group III-V and group IV composite switch includes a group IV transistor in a lower active die, the group IV transistor having a source and a gate situated on a bottom side of the lower active die. The group III-V and group IV composite switch also includes a group III-V transistor in an upper active die stacked over the lower active die, the group III-V transistor having a drain, a source, and a gate situated on a top side of the upper active die. The source of the group III-V transistor is electrically coupled to a drain of the group IV transistor using a through-semiconductor via (TSV) of the upper active die.

Abstract: Quantum-well-based semiconductor devices and methods of forming quantum-well-based semiconductor devices are described. A method includes providing a hetero-structure disposed above a substrate and including a quantum-well channel region. The method also includes forming a source and drain material region above the quantum-well channel region. The method also includes forming a trench in the source and drain material region to provide a source region separated from a drain region. The method also includes forming a gate dielectric layer in the trench, between the source and drain regions; and forming a gate electrode in the trench, above the gate dielectric layer.

Abstract: There are disclosed herein various implementations of composite semiconductor devices with active oscillation control. In one exemplary implementation, a normally OFF composite semiconductor device comprises a normally ON III-nitride power transistor and a low voltage (LV) device cascoded with the normally ON III-nitride power transistor to form the normally OFF composite semiconductor device. The LV device may be configured to include one or both of a reduced output resistance due to, for example, a modified body implant and a reduced transconductance due to, for example, a modified oxide thickness to cause a gain of the composite semiconductor device to be less than approximately 10,000.

Abstract: A semiconductor device includes: a substrate; a gate electrode which is arranged on a first surface of the substrate and has a plurality of gate finger electrodes, a source electrode which is arranged on the first surface of the substrate and has a plurality of source finger electrodes, the source finger electrode is close to the gate finger electrode; a drain electrode which is arranged on the first surface of the substrate and has a plurality of drain finger electrodes, the drain finger electrode faces the source finger electrode via the gate finger electrode; and a shield plate electrode which is arranged on the drain finger electrode and the first surface of the substrate between the gate finger electrode and the drain finger electrode via an insulating layer, is short-circuited to the source finger electrode, and shields electrically the gate finger electrode and the drain finger electrode from each other.

Abstract: A semiconductor device has a shield plate electrode short-circuited to a source electrode near the drain electrode. The shield plate electrode is connected to the source terminal electrode which has a VIA hole via the first line of air-bridge structure or overlay structure.

Abstract: A semiconductor device, comprising: a substrate; a plurality of gate finger electrodes which are arranged on the substrate; a plurality of source finger electrodes which are arranged on the substrate, each source finger electrode is close to the gate finger electrode; a plurality of drain finger electrodes which are arranged on the substrate, each drain finger electrode faces the source finger electrode via the gate finger electrode; a shield plate electrode which is arranged via an insulating layer over the drain finger electrode and the first surface of the substrate between the gate finger electrode and the drain finger electrode, is short-circuited to the source finger electrode, and shields electrically the gate finger electrode and the drain finger electrode from each other; and a slot VIA hole which is formed in the substrate under the source finger electrode and is connected to the source finger electrode.

Abstract: A semiconductor device has a shield plate electrode connected to a source terminal electrode near a drain electrode. The source terminal electrode is arranged between an active region AA and a drain terminal electrode, and a shield plate electrode is connected to the source terminal electrode.

Abstract: An embodiment of a transistor device includes a compound semiconductor material on a semiconductor carrier and a source region and a drain region spaced apart from each other in the compound semiconductor material with a channel region interposed between the source and drain regions. A Schottky diode is integrated with the semiconductor carrier, and contacts extend from the source and drain regions through the compound semiconductor material. The contacts are in electrical contact with the Schottky diode so that the Schottky diode is connected in parallel between the source and drain regions. In another embodiment, the integrated Schottky diode is formed by a region of doped amorphous silicon or doped polycrystalline silicon disposed in a trench structure on the drain side of the device.

Abstract: A semiconductor device according to the present invention includes a substrate; a nitride semiconductor layer formed above the substrate and having a laminated structure including at least three layers; a heterojunction bipolar transistor formed in a region of the nitride semiconductor layer; and a field-effect transistor formed in a region of the nitride semiconductor layer, the region being different from the region in which the heterojunction bipolar transistor is formed.

Abstract: Provided are a variable field effect transistor (FET) designed to suppress a reduction of current between a source and a drain due to heat while decreasing a temperature of the FET, and an electrical and electronic apparatus including the variable gate FET. The variable gate FET includes a FET and a gate control device that is attached to a surface or a heat-generating portion of the FET and is connected to a gate terminal of the FET so as to vary a voltage of the gate terminal. A channel current between the source and drain is controlled by the gate control device that varies the voltage of the gate terminal when the temperature of the FET increases above a predetermined temperature.

Abstract: Electronic modules, and methods of forming and operating modules, are described. The modules include a capacitor, a first switching device, and a second switching device. The electronic modules further include a substrate such as a DBC substrate, which includes an insulating layer between a first metal layer and a second metal layer, and may include multiple layers of DBC substrates stacked over one another. The first metal layer includes a first portion and a second portion isolated from one another by a trench formed through the first metal layer between the two portions. The first and second switching devices are over the first metal layer, a first terminal of the capacitor is electrically connected to the first portion of the first metal layer, and a second terminal of the capacitor is electrically connected to the second portion of the first metal layer, with the capacitor extending over the trench.

Abstract: Disclosed herein is a monolithic semiconductor device including: a substrate; a high electron mobility transistor (HEMT) structure that is a first device structure formed on the substrate; and a laterally diffused metal oxide field effect transistor (LDMOSFET) structure that is a second device structure formed to be connected with the HEMT structure on the substrate.The monolithic semiconductor device according to preferred embodiments of the present invention is a device having characteristics of a normally-off device while maintaining high current characteristics in a normally-on state, thereby improving high current and high voltage operation characteristics.

Abstract: A high electron mobility transistor (HEMT) according to example embodiments includes a first semiconductor layer, a second semiconductor layer on the first semiconductor layer, and a reverse diode gate structure on the second semiconductor layer. A source and a drain may be on at least one of the first semiconductor layer and the second semiconductor layer. A gate electrode may be on the reverse diode gate structure.

Abstract: A circuit includes input drain, source and gate nodes. The circuit also includes a group III nitride enhancement-mode HFET having a source, drain and gate and a voltage shifter having a first terminal connected to the gate of the enhancement mode HFET at a common junction. The circuit also includes a load resistive element connected to the common junction. The drain of the enhancement-mode HFET serves as the input drain node, the source of the enhancement-mode HFET serves as the input source node and a second terminal of the voltage shifter serves as the input gate node.

Abstract: A silicon substrate with a GaN-based device and a Si-based device on the silicon substrate is provided. The silicon substrate includes the GaN-based device on a SiC crystalline region. The SiC crystalline region is formed in the silicon substrate. The silicon substrate also includes the Si-based device on a silicon region, and the silicon region is next to the SiC crystalline region on the silicon substrate.

Abstract: A complementary logic device includes: an insulating layer formed on a substrate; a source electrode formed of a ferromagnetic body on the insulating layer; a gate insulating film; a gate electrode formed on the gate insulating film and controlling a magnetization direction of the source electrode; a channel layer formed on each of a first side surface and a second side surface of the source electrode and transmitting spin-polarized electrons from the source electrode; a first drain electrode formed on the first side surface of the source electrode; and a second drain electrode formed on the second side surface of the source electrode, wherein a magnetization direction of the first drain electrode and a magnetization direction of the second drain electrode are antiparallel to each other. Therefore, not only characteristics of low power and high speed but also characteristics of non-volatility and multiple switching by spin may be obtained.

Abstract: An optically active material is used to create power devices and circuits having significant performance advantages over conventional methods for affecting optical control of power electronics devices and circuits. A silicon-carbide optically active material is formed by compensating shallow donors with the boron related D-center. The resulting material can be n-type or p-type but it is distinguished from other materials by the ability to induce persistent photoconductivity in it when illuminated by electromagnetic radiation with a photon energy in excess of the threshold energy required to photoexcite electrons from the D-center to allowed states close to the conduction band edge, which varies from polytype to polytype.

Abstract: A III-nitride heterojunction semiconductor device having a III-nitride heterojunction that includes a discontinuous two-dimensional electron gas under a gate thereof.

Abstract: A semiconductor device according to the present invention includes a substrate; a nitride semiconductor layer formed above the substrate and having a laminated structure including at least three layers; a heterojunction bipolar transistor formed in a region of the nitride semiconductor layer; and a field-effect transistor formed in a region of the nitride semiconductor layer, the region being different from the region in which the heterojunction bipolar transistor is formed.

Abstract: A semiconductor device having a transistor and a rectifier includes: a current path; a first main electrode having a rectifying function and arranged on one end of the current path; a second main electrode arranged on the other end of the current path; an auxiliary electrode arranged in a region of the current path between the first main electrode and the second main electrode; a third main electrode arranged on the one end of the current path apart from the first main electrode along a direction intersecting the current path; and a control electrode arranged in a region of the current path between the second main electrode and the third main electrode. The transistor includes the current path, the second main electrode, the third main electrode, and the control electrode. The rectifier includes the current path, the first main electrode, the second main electrode, and the auxiliary electrode.

Abstract: A semiconductor device includes a semiconductor layer stack formed on a substrate, a first ohmic electrode and a second ohmic electrode which are formed on the semiconductor layer stack, and are spaced from each other, a first control layer formed between the first ohmic electrode and the second ohmic electrode, and a first gate electrode formed on the first control layer. The first control layer includes a lower layer, an intermediate layer which is formed on the lower layer, and has lower impurity concentration than the lower layer, and an upper layer which is formed on the intermediate layer, and has higher impurity concentration than the intermediate layer.

Abstract: A field-effect semiconductor device such as a HEMT or MESFET is monolithically integrated with a Schottky diode for feedback, regeneration, or protection purposes. The field-effect semiconductor device includes a main semiconductor region having formed thereon a source, a drain, and a gate between the source and the drain. Also formed on the main semiconductor region, preferably between gate and drain, is a Schottky electrode electrically coupled to the source. The Schottky electrode provides a Schottky diode in combination with the main semiconductor region. A current flow is assured from Schottky electrode to drain without interruption by a depletion region expanding from the gate.

Abstract: An embodiment of the present invention concerns a layered epitaxial structure for enhancement/depletion PHEMT devices, an enhancement/depletion PHEMT device and a method for manufacturing an enhancement/depletion PHEMT device that finds advantageous, but not exclusive, application in the manufacturing of integrated circuits operating at millimetre-wave and microwave frequencies.

Abstract: A semiconductor device includes: a first semiconductor layer made of an AlxGa1?xN (0?×<1); a second semiconductor layer provided on the first semiconductor layer and made of an undoped or first conductivity type AlyGa1?yN (0<y?1, x<y); an anode electrode and a cathode electrode which are connected to the second semiconductor layer; and a third semiconductor layer of second conductivity type provided between the anode electrode and the cathode electrode when viewed from a direction perpendicular to an upper surface of the second semiconductor layer. The third semiconductor layer is depleted when a predetermined magnitude or more of voltage is applied between the anode electrode and the cathode electrode.

Abstract: Provided is a nitride semiconductor device including: a nitride semiconductor layer over a substrate wherein the nitride semiconductor has a two-dimensional electron gas (2DEG) channel inside; a drain electrode in ohmic contact with the nitride semiconductor layer; a source electrode spaced apart from the drain electrode, in Schottky contact with the nitride semiconductor layer, and having an ohmic pattern in ohmic contact with the nitride semiconductor layer inside; a dielectric layer formed on the nitride semiconductor layer between the drain electrode and the source electrode and on at least a portion of the source electrode; and a gate electrode disposed on the dielectric layer to be spaced apart from the drain electrode, wherein a portion of the gate electrode is formed over a drain-side edge portion of the source electrode with the dielectric layer interposed therebetween, and a manufacturing method thereof.

Abstract: A high electron mobility transistor includes a source, gate and drain, a first III-V semiconductor region having a two-dimensional electron gas (2DEG) which provides a first conductive channel controllable by the gate between the source and drain, and a second III-V semiconductor region below the first III-V semiconductor region and having a second conductive channel connected to the source or drain and not controllable by the gate. The first and second III-V semiconductor regions are spaced apart from one another by a region of the high electron mobility transistor having a different band gap than the first and second III-V semiconductor regions.

Abstract: A semiconductor device includes: a compound semiconductor substrate; an n-channel field-effect transistor region formed on the compound semiconductor substrate, and that includes a first channel layer; an n-type first barrier layer that forms a heterojunction with the first channel layer, and supplies an n-type charge to the first channel layer; and a p-type gate region that has a pn junction-type potential barrier against the n-type first barrier layer; and a p-channel field-effect transistor region formed on the compound semiconductor substrate, and that includes a p-type second channel layer, and an n-type gate region that has a pn junction-type potential barrier against the p-type second channel layer.

Abstract: A hybrid device including a silicon based MOSFET operatively connected with a GaN based device.

Abstract: A circuit includes input drain, source and gate nodes. The circuit also includes a group III nitride enhancement-mode HFET having a source, drain and gate and a voltage shifter having a first terminal connected to the gate of the enhancement mode HFET at a common junction. The circuit also includes a load resistive element connected to the common junction. The drain of the enhancement-mode HFET serves as the input drain node, the source of the enhancement-mode HFET serves as the input source node and a second terminal of the voltage shifter serves as the input gate node.

Abstract: In a high-frequency circuit, it is necessary to block galvanically between active elements such as transistors and between an active element and an external terminal, and thus MIM capacitors or the like are used frequently. Among these MIM capacitors, one coupled to the external terminal is easily affected by static electricity from outside, which easily causes a problem of electro-static breakdown or the like. The present invention is a semiconductor integrated circuit device formed over a semi-insulating compound semiconductor substrate in which a first electrode of an MIM capacitor electrically coupled to an external pad is electrically coupled to the semi-insulating compound semiconductor substrate, and on the other side, a second electrode of the MIM capacitor is electrically coupled to the semi-insulating compound semiconductor substrate.

Abstract: There are disclosed herein various implementations of nested composite diodes. In one implementation, a nested composite diode includes a primary transistor coupled to a composite diode. The composite diode includes a low voltage (LV) diode cascoded with an intermediate transistor having a breakdown voltage greater than the LV diode and less than the primary transistor. In one implementation, the primary transistor may be a group III-V transistor and the LV diode may be an LV group IV diode.

Abstract: Disclosed herein are a nitride semiconductor device, a method for manufacturing the same, and a nitride semiconductor power device. According to an exemplary embodiment of the present invention, a nitride semiconductor device includes: a nitride semiconductor layer over a substrate wherein the nitride semiconductor layer has a two-dimensional electron gas (2DEG) channel formed therein; a D-mode FET that includes a gate electrode Schottky-contacting with the nitride semiconductor layer to form a normally-on operating depletion-mode (D-mode) HEMT structure; and a Schottky diode part that includes an anode electrode Schottky-contacting with the nitride semiconductor layer and increases a gate driving voltage of the D-mode FET, the anode electrode being connected to the gate electrode of the D-mode FET. In addition, the nitride semiconductor power device and the method for manufacturing a nitride semiconductor device are proposed.

Abstract: An enhancement mode III-Nitride device has a floating gate spaced from a drain electrode which is programmed by charges injected into the floating gate to form a permanent depletion region which interrupts the 2-DEG layer beneath the floating gate. A conventional gate is formed atop the floating gate and is insulated therefrom by a further dielectric layer. The device is a normally off E mode device and is turned on by applying a positive voltage to the floating gate to modify the depletion layer and reinstate the 2-DEG layer. The device is formed by conventional semiconductor fabrication techniques.