Abstract: A gallium nitride semiconductor device is disclosed that can be made by an easy manufacturing method. The device includes a silicon substrate, buffer layers formed on the top surface of the silicon substrate, and gallium nitride grown layers formed thereon. The silicon substrate has trenches 12 formed from the bottom surface, each trench having a depth reaching the gallium nitride grown layer through the silicon substrate and the buffer layers. The inside surface of each of the trenches and the bottom surface of the silicon substrate is covered with a drain electrode as a metal film. The vertical gallium nitride semiconductor device with this structure allows an electric current to flow in the direction of the thickness of the silicon substrate regardless of the resistance values of the gallium nitride grown layers and the buffer layers.

Abstract: The mechanisms of forming SiC crystalline regions on Si substrate described above enable formation and integration of GaN-based devices and Si-based devices on a same substrate. The SiC crystalline regions are formed by implanting carbon into regions of Si substrate and then annealing the substrate. An implant-stop layer is used to cover the Si device regions during formation of the SiC crystalline regions.

Abstract: Passivated semiconductor nanoparticles and methods for the fabrication and use of passivated semiconductor nanoparticles is provided herein.

Abstract: Disclosed is a semiconductor device including: a base substrate; a semiconductor layer disposed on the base substrate; an ohmic electrode part which has ohmic electrode lines disposed in a first direction, on the semiconductor layer; and a Schottky electrode part which is disposed to be spaced apart from the ohmic electrode lines on the semiconductor layer and includes Schottky electrode lines disposed in the first direction, wherein the Schottky electrode lines and the ohmic electrode lines are alternately disposed in parallel, and the ohmic electrode part further includes first ohmic electrodes covered by the Schottky electrode lines on the semiconductor layer.

Abstract: The present invention provides novel silicon-germanium hydride compounds, methods for their synthesis, methods for their deposition, and semiconductor structures made using the novel compounds.

Abstract: A semiconductor apparatus includes: a semiconductor apparatus includes: a first semiconductor layer of a first conductivity type; a second semiconductor layer of a second conductivity type; and a third semiconductor layer of the first conductivity type, wherein: the second semiconductor layer is formed between the first and third semiconductor layers, and the first and second semiconductor layers are in contact with each other; and a first energy level at a bottom edge of a conduction band of the first semiconductor layer is lower than a second energy level at a top edge of a valence band of the second semiconductor layer, and the second energy level at the top edge of the valence band of the second semiconductor layer is substantially the same as a third energy level at a bottom edge of a conduction band of the third semiconductor layer.

Abstract: A method of forming a strained, semiconductor-on-insulator substrate includes forming a second semiconductor layer on a first semiconductor substrate. The second semiconductor is lattice matched to the first semiconductor substrate such that the second semiconductor layer is subjected to a first directional stress. An active device semiconductor layer is formed over the second semiconductor layer such that the active device semiconductor layer is initially in a relaxed state. One or more trench isolation structures are formed through the active device layer and through the second semiconductor layer so as to relax the second semiconductor layer below the active device layer and impart a second directional stress on the active device layer opposite the first directional stress.

Abstract: A semiconductor device and a method of forming a structure in a target substrate for manufacturing a semiconductor device is provided. The method comprises the step of providing a masking layer on the target substrate and providing a stair-like profile in the masking layer such that the height of a step of the stair-like profile is smaller than the thickness of the masking layer. Further, the method comprises the step of performing anisotropic etching of the masking layer and the target substrate simultaneously such that a structure having a stair-like profile is formed in the target substrate. The semiconductor device comprises a target substrate including a first region made of a first type of semiconductor material and a second region made of a second type of semiconductor material.

Abstract: A photoactive device is provided. The device includes a first electrode, a second electrode, and a photoactive region disposed between and electrically connected to the first and second electrodes. The photoactive region further includes an organic donor layer and an organic acceptor layer that form a donor-acceptor heterojunction. The mobility of holes in the organic donor region and the mobility of electrons in the organic acceptor region are different by a factor of at least 100, and more preferably a factor of at least 1000. At least one of the mobility of holes in the organic donor region and the mobility of electrons in the organic acceptor region is greater than 0.001 cm2/V-sec, and more preferably greater than 1 cm2/V-sec. The heterojunction may be of various types, including a planar heterojunction, a bulk heterojunction, a mixed heterojunction, and a hybrid planar-mixed heterojunction.

Abstract: Provided is an epitaxial substrate for a semiconductor device, which has excellent schottky contact characteristics that are stable over time. The epitaxial substrate for a semiconductor device includes a base substrate, a channel layer formed of a first group III nitride containing at least Ga and having a composition of Inx1Aly1Gaz1N (x1+y1+z1=1), and a barrier layer formed of a second group III nitride containing at least In and Al and having a composition of Inx2Aly2Gaz2N (x2+y2+z2=1), wherein the barrier layer has tensile strains in an in-plane direction, and pits are formed on a surface of the barrier layer at a surface density of 5×107/cm2 or more and 1×109/cm2 or less.

Abstract: Disclosed are a non-polar hetero substrate, a method for manufacturing the same, and a nitride-based light emitting device using the same. The non-polar hetero substrate includes a non-polar base substrate, a nitride base layer disposed on the substrate, a defect reduction layer disposed on the nitride base layer, the defect reduction layer including a plurality of air gaps, and a nitride semiconductor layer disposed on the defect reduction layer.

Abstract: A semiconductor device which is designed based on RDR, suppresses the occurrence of a trouble at the boundary between an active region and a power wire and therearound and is small in size and highly integrated. The semiconductor device includes a first conductive impurity region for functional elements which is formed over the main surface of a semiconductor substrate and a second conductive impurity region for power potential to which power potential is applied in at least one standard cell. It also includes insulating layers which are formed over the main surface of the semiconductor substrate and have throughholes reaching the main surface of the semiconductor substrate, and a conductive layer for contact formed in the throughholes of the insulating layers.

Abstract: A method including producing a monocrystalline layer is disclosed. A first lattice constant on a monocrystalline substrate has a second lattice constant at least in a near-surface region. The second lattice constant is different from the first lattice constant. Lattice matching atoms are implanted into the near-surface region. The near-surface region is momentarily melted. A layer is epitaxially deposited on the near-surface region that has solidified in monocrystalline fashion.

Abstract: A method and a semiconductor device for incorporating defect mitigation structures are provided. The semiconductor device comprises a substrate, a defect mitigation structure comprising a combination of layers of doped or undoped group IV alloys and metal or non-metal nitrides disposed over the substrate, and a device active layer disposed over the defect mitigation structure. The defect mitigation structure is fabricated by depositing one or more defect mitigation layers comprising a substrate nucleation layer disposed over the substrate, a substrate intermediate layer disposed over the substrate nucleation layer, a substrate top layer disposed over the substrate intermediate layer, a device nucleation layer disposed over the substrate top layer, a device intermediate layer disposed over the device nucleation layer, and a device top layer disposed over the device intermediate layer.

Abstract: The present invention relates to a method that involves providing a stack of a first substrate and a InGaN seed layer formed on the first substrate, growing an InGaN layer on the InGaN seed layer to obtain an InGaN-on-substrate structure, forming a first mirror layer overlaying the exposed surface of the grown InGaN layer, attaching a second substrate to the exposed surface of the mirror layer, detaching the first substrate from the InGaN seed layer and grown InGaN layer to expose a surface of the InGaN seed layer opposite the first mirror layer, and forming a second mirror layer overlaying the opposing surface of the InGaN seed layer.

Abstract: A semiconductor structure having a transistor and a thermo electronic structure. The transistor has a control electrode for controlling a flow of carriers through a semiconductor layer between a pair of electrodes. The thermo electronic structure has a first portion disposed on at least one of the pair of electrodes and a second portion disposed over a region of the semiconductor layer proximate the control electrode between the control electrode and said at least one of the pair of electrode. The thermo electronic structure extends from the first portion to the second portion for removing heat generated heat from said region in the semiconductor layer.

Abstract: The invention provides semiconductor materials including a gallium nitride material layer formed on a silicon substrate and methods to form the semiconductor materials. The semiconductor materials include a transition layer formed between the silicon substrate and the gallium nitride material layer. The transition layer is compositionally-graded to lower stresses in the gallium nitride material layer which can result from differences in thermal expansion rates between the gallium nitride material and the substrate. The lowering of stresses in the gallium nitride material layer reduces the tendency of cracks to form. Thus, the invention enables the production of semiconductor materials including gallium nitride material layers having few or no cracks. The semiconductor materials may be used in a number of microelectronic and optical applications.

Abstract: To provide a semiconductor device including a functional laminate having flatness and crystallinity improved by effectively passing on the crystallinity and flatness improved in a buffer to the functional laminate, and to provide a method of producing the semiconductor device; in the semiconductor device including the buffer and the functional laminate having a plurality of nitride semiconductor layers, the functional laminate includes a first n-type or i-type AlxGa1-xN layer (0?x<1) on the buffer side, and an AlzGa1-zN adjustment layer containing p-type impurity, which has an approximately equal Al composition to the first AlxGa1-xN layer (x?0.05?z?x+0.05, 0?z<1) is provided between the buffer and the functional laminate.

Abstract: The present invention describes a hybrid integrated circuit comprising both CMOS and III-V devices, monolithically integrated in a single chip. It allows the almost complete elimination of the contamination issues related to the integration of different technologies, maintaining at the same time a good planarization of the structure. It further simplifies the fabrication process, allowing the growth of high quality III-V materials on (100) silicon substrates lowering the manufacturing cost. Moreover, differently from many prior art attempts, it does not require silicon on insulator technologies and/or other expensive process steps. This invention enables the consolidation on the same integrated circuit of a hybrid switching power converter that takes advantage of the established circuit topologies of CMOS circuitries and of the higher mobility and voltage withstanding of III-V HEMT devices.

Abstract: A semiconductor structure and a method for forming the same are provided. The semiconductor structure includes a wafer; a plurality of convex structures formed on the wafer, in which every two adjacent convex structures are separated by a cavity in a predetermined pattern and arranged in an array, and the cavity between every two adjacent convex structures is less than 50 nm in width; and a first semiconductor film formed on the plurality of convex structures, in which a part of the first semiconductor film is spaced apart from the wafer.

Abstract: A semiconductor device includes a p-type semiconductor layer and an n-type semiconductor layer that are joined by sandwiching a depletion layer with a thickness that allows transmission of a plurality of electrons and holes by direct-tunneling.

Abstract: Using a laser lift-off (LLO) nonbonding technique, freestanding 4-layer GaN/AlGaN heterostructure membranes have been formed. A 4×4 mm mask was attached to the area at the center of the most-upper AlGaN layer was attached using a nonbonding material such as vacuum grease. A microscopic slide attached by an adhesive provided support for the structure during the laser lift-off without bonding to the layers. The vacuum grease and the mask isolated the adhesive from the structure at the center. The microscopic slide served as a temporarily nonbonding handle substrate. Laser lift-off of the sapphire substrate from the heterostructures was performed. The remaining adhesive served as a supporting frame for the structure making a free-standing 4-layer GaN/AGaN heterostructure membrane. Other frameless freestanding membranes can be fabricated for a variety of applications including further III-nitride growth, heterogeneous integration, packaging of micro systems, and thin film patterns.

Abstract: Provided is a semiconductor wafer including: a base wafer whose surface is made of a silicon crystal: a SixGe1-xC (0?x<1) epitaxial crystal formed in a partial area of the silicon crystal; and a Group 3 nitride semiconductor crystal formed on the SixGe1-xC (0?x<1) epitaxial crystal. In one example, the semiconductor wafer includes an inhibitor that is formed on the silicon crystal, contains an aperture exposing the silicon crystal, and inhibits crystal growth, and the SixGe1-xC (0?x<1) epitaxial crystal is formed in the aperture.

Abstract: A semiconductor structure is provided, comprising: a Si substrate; a porous structure layer formed on the Si substrate, in which the porous structure layer has a flat surface and comprises a Si1-xGex layer with low Ge content; and a Ge-containing layer formed on the porous structure layer, in which the Ge-containing layer comprises a Ge layer or a Si1-yGey layer with high Ge content and x?y. Further, a method for forming the semiconductor structure is also provided.

Abstract: Methods and substrates for laser annealing are disclosed. The substrate includes a target region to be annealed and a plurality of reflective interfaces. The reflective interfaces cause energy received by the substrate to resonate within the target region. The method includes emitting energy toward the substrate with a laser, receiving the energy with the substrate, and reflecting the received energy with a plurality of reflective interfaces embedded in the substrate to generate a resonance within the target region.

Abstract: A semiconductor light-emitting device includes a GaAs substrate; and an active layer provided over the GaAs substrate, the active layer including: a lower barrier layer lattice-matched to the GaAs substrate; a quantum dot provided on the lower barrier layer; a strain relaxation layer covering a side of the quantum dot; and an upper barrier layer contacting the top of the quantum dot, at least a portion of the upper barrier layer contacting the top of the quantum dot being lattice-matched to the GaAs substrate, and having a band gap larger than a band gap of the quantum dot and smaller than a band gap of GaAs.

Abstract: Formation of transistors, such as, e.g., PMOS transistors, with diffusion regions having different depths for equalization of performance among transistors of an integrated circuit is described. Shallow-trench isolation structures are formed in a substrate formed at least in part of silicon for providing the transistors with at least substantially equivalent channel widths and lengths. A series of masks and etches is performed to form first recesses and second recesses defined in the silicon having different depths and respectively associated with first and second transistors. The second recesses are deeper than the first recesses. A silicon germanium film is formed in the first recesses and the second recesses. The silicon germanium film in the second recesses is thicker than the silicon germanium film in the first recesses, in order to increase performance of the second transistor so it is closer to the performance of the first transistor.

Abstract: A semiconductor heterostructure (10) includes a crystalline substrate of a first semiconductor material and a mask (11) disposed over a surface of the crystalline substrate. The mask (11) has openings (12) including a plurality of elongated opening sections (13, 14) with a width (w) less than or equal to 900 nm. At least one first section (13) of the elongated opening sections is directed non-parallel relative to at least one second section (14) of the elongated opening sections. The semiconductor heterostructure (10) further includes an overgrowth crystalline layer of a second semiconductor material, filling the openings (12) and covering the mask. A method for manufacturing of such a semiconductor heterostructure is also presented.

Abstract: An intermediate product in the manufacture of a vertical multiple-channel FET device containing alternating —Si—[(SiGe)—Si]u- stacked layers is shown, as well as a process for selectively etching the SiGe layers in such a stacked layer system, and products obtained from such selective etching. Differential Ge content is added to the successive layers to provide uniform removal of the sacrificial SiGe layers.

Abstract: The present invention provides a fabrication method of a semiconductor substrate, by which a planar GaN substrate that is easily separated can be fabricated on a heterogeneous substrate, and a semiconductor device which is fabricated using the GaN substrate. The semiconductor substrate comprises a substrate, a first semiconductor layer arranged on the substrate, a metallic material layer arranged on the first semiconductor layer, a second semiconductor layer arranged on the first semiconductor layer and the metallic material layer, and voids formed in the first semiconductor layer under the metallic material layer.

Abstract: A transistor comprising an active region, with source and drain electrodes formed in contact with the active region and a gate formed between the source and drain electrodes and in contact with the active region. A first spacer layer is on at least part of the surface of the active region between the gate and the drain electrode and between the gate and the source electrode. The gate comprises a generally t-shaped top portion that extends toward the source and drain electrodes. A field plate is on the spacer layer and under the overhand of at least one section of the gate top portion. The field plate is at least partially covered by a second spacer layer, with the second spacer layer on at least part of the surface of the first active layer and between the gate and the drain and between the gate and the source. At least one conductive path electrically connects the field plate to the source electrode or the gate.

Abstract: Oligomers and/or polymers comprising a backbone comprising arylamine and fluorinated alkyleneoxy moieties which may be crosslinked. Ink formulations and devices can be formed from the oligomers or polymers, or corresponding monomers. Doped compositions can be formed. Charge injection and transport layers can be formed. Improved stability can be achieved in organic electronic devices such as OLEDs and OPVs.

Abstract: A nitride semiconductor device in which contact resistance between an ohmic electrode and an ohmic recess portion is reduced and a method of manufacturing the nitride semiconductor device are provided. The nitride semiconductor device includes: a first nitride semiconductor layer formed on a substrate; a second nitride semiconductor layer formed on the first nitride semiconductor layer and having a bandgap wider than a bandgap of the first nitride semiconductor layer; an ohmic recess portion formed in at least the second nitride semiconductor layer; and an ohmic electrode provided in contact with the ohmic recess portion. The ohmic recess portion includes a corrugated structure in at least a part of a plane in contact with the ohmic electrode.

Abstract: A semiconductor device includes a semiconductor chip having a surface provided with connecting electrodes, a stacked structure made up of alternately stacked dielectric and wiring layers and provided on the surface of the semiconductor chip, a passive element provided in the stacked structure and electrically connected to the wiring layers; and external electrodes for external electrical connection provided on the stacked structure and electrically connected to the connecting electrodes via the wiring layers. The passive element has at least one layer selected from a group consisting of a capacitor dielectric layer, a resistor layer and a conductor layer that are formed by spraying an aerosol particulate material.

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: A semiconductor device comprises: a semiconductor substrate located on an insulating layer; and an insulator located on the insulating layer and embedded in the semiconductor substrate, wherein the insulator applies stress therein to the semiconductor substrate. A method for forming a semiconductor device comprises: forming a semiconductor substrate on an insulating layer; forming a cavity within the semiconductor substrate so as to expose the insulating layer; forming an insulator in the cavity, wherein the insulator applies stress therein to the semiconductor substrate. It facilitates the reduction of the short channel effect, the resistance of source/drain regions and parasitic capacitance.

Abstract: Embodiments of the present disclosure relate to a novel semiconductor. In one aspect, the semiconductor may include a transparent layer having a first surface, a first doped layer, a second doped layer, and an active layer. The first doped layer may be formed over the first surface of the transparent layer and have a plurality of first-type electrodes formed thereon. The second doped layer may be formed over the first surface of the transparent layer and have a plurality of second-type electrodes formed thereon. The active layer may be formed between the first doped layer and the second doped layer. A distance between at least one of the first-type electrodes and a nearest other one of the first-type electrodes may be greater than each of respective distances between the at least one of the first-type electrodes and more than two of the second-type electrodes.

Abstract: A vertical power transistor device comprises: a substrate formed from a III-V semiconductor material and a multi-layer stack at least partially accommodated in the substrate. The multi-layer stack comprises: a semi-insulating layer disposed adjacent the substrate and a first layer formed from a first III-V semiconductor material and disposed adjacent the semi-insulating layer. The multi-layer stack also comprises a second layer formed from a second III-V semiconductor material disposed adjacent the first layer and a heterojunction is formed at an interface of the first and second layers.

Abstract: According to one embodiment, a nitride semiconductor stacked structure having a first surface includes a substrate, a first buffer layer, a first crystal layer, a second buffer layer and a second crystal layer. A step portion is provided in the substrate and includes an upper surface, a lower surface, and a side surface between the upper surface and the lower surface. The first buffer layer includes InsAltGa1-s-tN (0?s?0.05, 0?t?1) and covers the lower surface and the side surface. The first crystal layer is provided on the first buffer layer, includes InsAltGa1-s-tN (0?s?0.05, 0?t?0.05), and has an upper surface provided above the upper surface of the substrate. The second buffer layer includes InsAltGa1-s-tN (0?s?0.05, 0?t?1) and continuously covers the upper surface of the first crystal layer and the upper surface of the substrate. The second crystal layer covers the second buffer layer, includes InsAltGa1-s-tN (0?s?0.05, 0?t?0.05), and has the first surface.

Abstract: There is provided a light emitting device, which comprises compound semiconductor layers including a first conductive semiconductor layer, an active layer and a second conductive semiconductor layer; a metal reflection layer formed on a region of the second conductive semiconductor layer; an insulating structure formed at least in a boundary region of the second conductive semiconductor layer; a metal material structure formed to cover the second conductive semiconductor layer having the metal reflection layer and the insulating structure formed; and a substrate bonded to the metal material structure, wherein the boundary region of the second conductive semiconductor layer includes an outer region of the second conductive semiconductor layer along an outer circumference of the second conductive semiconductor layer.

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: A nitride semiconductor substrate is featured in comprising: a GaN semiconductor layer grown on a base layer, which has a substantially triangular cross-section along the thickness direction thereof, a periodic stripe shapes, and uneven surfaces arranged on the stripes inclined surfaces; and an overgrown layer composed of AlGaN or InAlGaN on the GaN semiconductor layer.

Abstract: Semiconductor structures and methods of manufacture semiconductors are provided which relate to heterojunction bipolar transistors. The method includes forming two devices connected by metal wires on a same wiring level. The metal wire of a first of the two devices is formed by selectively forming a metal cap layer on copper wiring structures.

Abstract: A light emitting device according to the embodiment may include a light emitting structure including a first semiconductor layer, an active layer, and a second semiconductor layer; a first electrode on the light emitting structure; and a protection layer including a first metallic material on an outer peripheral region of one of the light emitting structure and the first electrode.

Abstract: Example embodiments relate to a heterojunction diode, a method of manufacturing the heterojunction diode, and an electronic device including the heterojunction diode. The heterojunction diode may include a first conductive type non-oxide layer and a second conductive type oxide layer bonded to the non-oxide layer. The non-oxide layer may be a Si layer. The Si layer may be a p++ Si layer or an n++ Si layer. A difference in work functions of the non-oxide layer and the oxide layer may be about 0.8-1.2 eV. Accordingly, when a forward voltage is applied to the heterojunction diode, rectification may occur. The heterojunction diode may be applied to an electronic device, e.g., a memory device.

Abstract: The present invention provides a multi-finger structure of a SiGe heterojunction bipolar transistor (HBT). It is consisted of plural SiGe HBT single cells. The multi-finger structure is in a form of C/BEBC/BEBC/.../C, wherein, C, B, E respectively stands for collector, base and emitter; CBEBC stands for a SiGe HBT single cell. The collector region is consisted of an n type ion implanted layer inside the active region. The bottom of the implanted layer is connected to two n type pseudo buried layers. The two pseudo buried layers are formed through implantation to the bottom of the shallow trenches that surround the collector active region. Two collectors are picked up by deep trench contact through the field oxide above the two pseudo buried layers. The present invention can reduce junction capacitance, decrease collector electrode output resistance, and improve device frequency characteristics.

Abstract: A semiconductor device and a method for manufacturing the same are disclosed. The method comprises: forming at least one trench in a first semiconductor layer, wherein at least lower portions of respective sidewalls of the trench tilt toward outside of the trench; filling a dielectric material in the trench, thinning the first semiconductor layer so that the first semiconductor layer is recessed with respect to the dielectric material, and epitaxially growing a second semiconductor layer on the first semiconductor layer, wherein the first semiconductor layer and the semiconductor layer comprise different materials from each other. According to embodiments of the disclosure, defects occurring during the heteroepitaxial growth can be effectively suppressed.

Abstract: A compound semiconductor substrate which inhibits the generation of a crack or a warp and is preferable for a normally-off type high breakdown voltage device, arranged that a multilayer buffer layer 2 in which AlxGa1-xN single crystal layers (0.6?X?1.0) 21 containing carbon from 1×1018 atoms/cm3 to 1×1021 atoms/cm3 and AlyGa1-yN single crystal layers (0.1?y?0.5) 22 containing carbon from 1×1017 atoms/cm3 to 1×1021 atoms/cm3 are alternately and repeatedly stacked in order, and a nitride active layer 3 provided with an electron transport layer 31 having a carbon concentration of 5×1017 atoms/cm3 or less and an electron supply layer 32 are deposited on a Si single crystal substrate 1 in order. The carbon concentrations of the AlxGa1-xN single crystal layers 21 and that of the AlGa1-yN single crystal layers 22 respectively decrease from the substrate 1 side towards the above-mentioned active layer 3 side. In this way, the compound semiconductor substrate is produced.

Abstract: A group III nitride semiconductor device having a gallium nitride based semiconductor film with an excellent surface morphology is provided. A group III nitride optical semiconductor device includes a group III nitride semiconductor supporting base, a GaN based semiconductor region, an active layer, and a GaN semiconductor region. The primary surface of the group III nitride semiconductor supporting base is not any polar plane, and forms a finite angle with a reference plane that is orthogonal to a reference axis extending in the direction of a c-axis of the group III nitride semiconductor. The GaN based semiconductor region, grown on the semipolar primary surface, includes a semiconductor layer of, for example, an n-type GaN based semiconductor doped with silicon. A GaN based semiconductor layer of an oxygen concentration of 5×1016 cm?3 or more provides an active layer, grown on the primary surface, with an excellent crystal quality.

Abstract: A semiconductor structure includes a semiconductor layer that is passivated with an aluminum-silicon nitride layer. When the semiconductor layer in particular comprises a III-V semiconductor material such as a group III nitride semiconductor material or a gallium nitride semiconductor material, the aluminum-silicon nitride material provides a superior passivation in comparison with a silicon nitride material.