Abstract: A circuit including an inverter is provided for a wiring layer. A semiconductor device is provided with a wiring layer circuit which is formed over an insulating film and includes at least one inverter element. The inverter is provided with a first transistor element and a resistance element which is connected to the first transistor via a connection node. The first transistor element is provided with a gate electrode which is embedded in an interlayer insulating film including the insulating film, a gate insulating film which is formed over the interlayer insulating film and the gate electrode, and a first semiconductor layer which is formed over the gate insulating film between a source electrode and a drain electrode. The resistance element is provided with a second semiconductor layer which functions as a resistance. The first semiconductor layer and the second semiconductor layer are formed in the same layer.

Abstract: An embodiment of the present invention provides a TFT array substrate comprising: a base substrate (1) and thin film transistors. The thin film transistor comprises a gate electrode (2), a semiconductor layer (5), a semiconductor protective layer, a source electrode (8) and a drain electrode (9). The semiconductor protective layer is disposed adjacent to the semiconductor layer (5) and comprises a composite lamination structure, which comprises a protective layer formed of an insulating material capable of preventing de-oxygen of the semiconductor layer (5) and an insulating layer formed of an insulating material to be etched more easily.

Abstract: A transistor has variation in a threshold voltage or mobility due to accumulation of factors such as variation in a gate insulating film which is caused by a difference of a manufacturing process or a substrate to be used and variation in a crystal state of a channel formation region. The present invention provides an electric circuit which is arranged such that both electrodes of a capacitance device can hold a voltage between the gate and the source of a specific transistor. Further, the present invention provides an electric circuit which has a function capable of setting a potential difference between both electrodes of a capacitance device so as to be a threshold voltage of a specific transistor.

Abstract: A semiconductor structure includes a barrier layer, a spacer structure, and a channel layer. The barrier layer includes a group III nitride. The spacer structure includes first and second aluminum nitride layers and an intermediate layer. The intermediate layer includes a group III nitride and is between the first and second aluminum nitride layers. The intermediate layer has a first free charge carrier density at an interface with the second aluminum nitride layer. The spacer structure is between the barrier layer and the channel layer. The channel layer includes a group III nitride and has a second free charge carrier density at an interface with the first aluminum nitride layer of the spacer structure. The first aluminum nitride layer, the intermediate layer, and the second aluminum nitride layer have layer thicknesses so the first free charge carrier density is less than 10% of the second free charge carrier density.

Abstract: A semiconductor device includes a metal substrate including a metal base plate, an insulating sheet located on the metal base plate, and a wiring pattern located on the insulating sheet, and a semiconductor element located on the metal substrate. The semiconductor element is sealed with a molding resin. The molding resin extends to side surfaces of the metal substrate. On the side surfaces of the metal substrate, the insulating sheet and the wiring pattern are not exposed from the molding resin, whereas the metal base plate includes a projecting portion exposed from the molding resin.

Abstract: There are provided a semiconductor device in which a drain leak current can be reduced in the transistor operation while high vertical breakdown voltage is achieved and a method for producing the semiconductor device. In the semiconductor device, an opening 28 that extends from an n+-type contact layer 8 and reaches an n-type drift layer 4 through a p-type barrier layer 6 is formed. The semiconductor device includes a regrown layer 27 located so as to cover portions of the p-type barrier layer 6 and the like that are exposed to the opening, the regrown layer 27 including an undoped GaN channel layer 22 and a carrier supply layer 26; an insulating layer 9 located so as to cover the regrown layer 27; and a gate electrode G located on the insulating layer 9. In the p-type barrier layer, the Mg concentration A (cm?3)and the hydrogen concentration B (cm?3) satisfy 0.1<B/A<0.9 . . . (1).

Abstract: The LED package comprises a substrate with a first conductive type through-hole and a second conductive type through-hole through the substrate; a reflective layer formed on an upper surface of the substrate; a LED die having first conductive type pad and second conductive type pad, wherein the first conductive type pad is aligned with the first conductive type through-hole; a slanting structure of dielectric layer formed adjacent at least one side of the LED die for carrying conductive traces; a conductive trace formed on upper surface of the slanting structure to offer path between the second conductive type pad and the conductive type through-hole; and a refilling material within the first conductive type through-hole and second conductive type through-hole.

Abstract: First chip main surfaces of first semiconductor chips are bonded to a heat spreader, and second chip main surfaces of the first semiconductor chips are bonded to a first electrode. First chip main surfaces of second semiconductor chips are bonded to a heat spreader, and second chip main surfaces of the second semiconductor chips are bonded to a first electrode. A plurality of electrodes are provided by a lead frame. An insulating member is provided on a side opposite to the chips when viewed from the heat spreader. An insulating substrate is provided on a side opposite to the chips when viewed from the first electrodes.

Abstract: A MOSFET includes: a substrate having a first trench formed therein, the first trench opening on a side of one main surface; a gate insulating film; and a gate electrode. The substrate includes an n type source region, a p type body region, an n type drift region, and a p type deep region making contact with the body region and extending to a region deeper than the first trench. The first trench is formed such that a distance between the wall surface and the deep region increases with increasing distance from the main surface of the substrate.

Abstract: A semiconductor substrate includes: a silicon substrate; a monocrystalline silicon carbide film formed on a surface of the silicon substrate; and a stress relieving film formed on the surface of the silicon substrate opposite from the side on which the monocrystalline silicon carbide film is formed, and that relieves stress in the silicon substrate by applying compressional stress to the silicon substrate surface on which the stress relieving film is formed, wherein a plurality of spaces is present in the monocrystalline silicon carbide film in portions on the side of the silicon substrate and along the interface between the monocrystalline silicon carbide film and the silicon substrate.

Abstract: Micropipe-free, single crystal, silicon carbide (SiC) and related methods of manufacture are disclosed. The SiC is grown by placing a source material and seed material on a seed holder in a reaction crucible of the sublimation system, wherein constituent components of the sublimation system including the source material, reaction crucible, and seed holder are substantially free from unintentional impurities. By controlling growth temperature, growth pressure, SiC sublimation flux and composition, and a temperature gradient between the source material and the seed material or the SiC crystal growing on the seed material during the PVT process, micropipe-inducing process instabilities are eliminated and micropipe-free SiC crystal is grown on the seed material.

Abstract: Various embodiments of methods and devices are provided for an optocoupler comprising an optically reflective compound comprising silicone and inner and outer surfaces. A molding compound surrounds and encapsulates at least portions of the outer surfaces of the optically reflective compound to form an enclosure. A surface functional coating layer is provided in the optically reflective compound to promote adhesion and increase breakdown voltages between inner walls of the enclosure and the outer surfaces of the optically reflective compound.

Abstract: Processing for a silicon photonics wafer is provided. A silicon photonics wafer that includes an active silicon photonics layer, a thin buried oxide layer, and a silicon substrate is received. The thin buried oxide layer is located between the active silicon photonics layer and the silicon substrate. An electrical CMOS wafer that includes an active electrical layer is also received. The active silicon photonics layer of the silicon photonics wafer is flip chip bonded to the active electrical layer of the electrical CMOS wafer. The silicon substrate is removed exposing a backside surface of the thin buried oxide layer. A low-optical refractive index backing wafer is added to the exposed backside surface of the thin buried oxide layer. The low-optical refractive index backing wafer is a glass substrate or silicon substrate wafer. The silicon substrate wafer includes a thick oxide layer that is attached to the thin buried oxide layer.

Abstract: Optical conversion layers based on semiconductor nanoparticles for use in lighting devices, and lighting devices including same. In various embodiments, spherical core/shell seeded nanoparticles (SNPs) or nanorod seeded nanoparticles (RSNPs) are used to form conversion layers with superior combinations of high optical density (OD), low re-absorbance and small FRET. In some embodiments, the SNPs or RSNPs form conversion layers without a host matrix. In some embodiments, the SNPs or RSNPs are embedded in a host matrix such as polymers or silicone. The conversion layers can be made extremely thin, while exhibiting the superior combinations of optical properties.

Abstract: In an organic light-emitting display device and a method of manufacturing the same, the organic light-emitting display device includes: a substrate; an organic light-emitting unit that includes a plurality of organic light-emitting devices formed on the substrate; and an encapsulation unit that seals the organic light-emitting unit. The encapsulation unit includes: a barrier layer and a planarization layer that are stacked on the organic light-emitting unit; and a cover layer that is disposed between the barrier layer and the planarization layer to cover a crack occurring in each of the organic light-emitting devices.

Abstract: A light emitting device has a base comprising at least one pair of leads having a silver-containing layer on their surfaces and being secured by a resin molded body, a light emitting element mounted on said leads, a protective film made of an inorganic material that covers the upper surface of said base, and a sealing resin disposed on the base surface via said protective film. The sealing resin has a first resin that covers said light emitting element, and a second resin having a higher hardness than said first resin that covers the boundaries between said resin molded body and said leads.

Abstract: A light emitting system and related method are disclosed.

Abstract: In accordance with certain embodiments, a semiconductor die is adhered directly to a yielding substrate with a pressure-activated adhesive notwithstanding any nonplanarity of the surface of the semiconductor die or non-coplanarity of the semiconductor die contacts.

Abstract: Disclosed is a semiconductor light emitting device. The semiconductor light emitting device comprises a first semiconductor layer, a second semiconductor layer, an active layer formed between the first semiconductor layer and the second semiconductor layer, a first reflective electrode on the first semiconductor layer to reflect incident light, and a second reflective electrode on the second semiconductor layer to reflect the incident light.

Abstract: The present invention relates to a manufacturing method of a composite substrate. The method includes the steps of: providing a substrate; providing a precursor of group III elements and a precursor of nitrogen (N) element alternately in an atomic layer deposition (ALD) process or a plasma-enhanced atomic layer deposition (PEALD) process so as to deposit a nitride buffer layer on the substrate; and annealing the nitride buffer layer on the substrate at a temperature in the range of 300° C. to 1600° C.

Abstract: A method of manufacturing a substrate, characterized by a first surface and a second surface, for use in a semiconductor device is provided. The method includes providing a mold having a first template and/or a second template corresponding to a first texture and a second texture respectively. Then, the method includes injection molding a material for the substrate in the mold, to form the substrate, such that the material is injection molded to create the first texture on the first surface and/or the second texture on the second surface. The first texture and/or the second texture facilitate light extraction or light trapping in the semiconductor device.

Abstract: Disclosed is an organic electroluminescent device and a method for manufacturing thereof, the device including a light emitting part in which a substrate, a first electrode, an organic light emitting layer and a second electrode, and a nano structure including a first opening part randomly distributed between the substrate and the first electrode, wherein the nano structure includes at least anyone of polyimide, epoxy, polycarbonate, PVC, PVP, polyethylene, polyacryl and perylene, each having a refractive index in the range of 1.3˜1.5, whereby a light extraction can be improved by restricting a reflective light from an interface between the substrate and the first electrode.

Abstract: A solid state lighting device, including: a housing, which has a reflective cup inside; a solid state light source, placed inside the housing; a transparent adhesive material, used to seal the solid state light source in the housing; and a multi-layer fluorescent structure, placed on the transparent adhesive material and having a fluorescent layer or a phosphor layer sandwiched by two transparent adhesive layers, so as to absorb light beams from the solid state light source and then emit light of longer wavelengths.

Abstract: A semiconductor light-emitting device having an electrode that can be manufactured by a simple method and is unlikely to deteriorate, and a method for forming the electrode are provided. The semiconductor light-emitting device according to the present invention has a semiconductor layered structure having a light-emitting layer that emits light by supplying electric power and an electrode formed on the semiconductor layered structure. The electrode has a reflection layer that reflects light exiting from the light-emitting layer, a barrier layer formed on the upper side and side surface of the reflection layer, and a pad layer formed only on the top surface of the barrier layer.

Abstract: A light-emitting device including: a light-emitting stacked layer having first conductivity type semiconductor layer, a light-emitting layer formed on the first conductivity type semiconductor layer, and a second conductivity type semiconductor layer formed on the light-emitting layer, wherein the upper surface of the second conductivity type semiconductor layer is a textured surface; a first planarization layer formed on a first part of the upper surface of the second conductivity type semiconductor layer; a first transparent conductive oxide layer formed on the first planarization layer and a second part of the second conductivity type semiconductor layer, including a first portion in contact with the first planarization layer and a second portion having a first plurality of cavities in contact with the second conductivity type semiconductor layer;; and a first electrode formed on the first portion of the first transparent conductive oxide layer.

Abstract: The present invention provides an LED light source, and particularly provides an illuminating device with an LED surface light source covered with an optical film. The device includes: an LED point light source, an illuminator, and a heat sink; wherein the illuminator is an optically transparent solid geometry with an optical film covering the outer surface thereof; wherein at least one outer surface of the solid geometry is an incident surface and at least one outer surface of the solid geometry is an emergence surface; and the optical film is a solid optical medium film; and the LED point light source is fixed on the heat sink, matching with the incident surface of the illuminator.

Abstract: A semiconductor component includes at least one optoelectronic semiconductor chip and a connecting carrier having a connecting surface on which the semiconductor chip is disposed. A reflective coating and a limiting structure are formed on the connecting carrier. The limiting structure at least partially encloses the semiconductor chip in the lateral direction, and the reflective coating at least partially extends in the lateral direction between a side surface of the semiconductor chip and the limiting structure.

Abstract: An optoelectronic semiconductor component comprising a light source, a housing and electrical connections, wherein the light source emits primary radiation having a peak wavelength in the range of 420 to 460 nm and having a flank of the primary emission which extends into the range less than 420 nm, wherein the radiation of the flank range or of part thereof is converted into visible radiation by an additive phosphor.

Abstract: A light emitting device includes: a laminated body including a first-conductivity type semiconductor layer, a light emitting layer, and a second-conductivity type semiconductor layer in this order; a contact layer provided in contact with the second-conductivity type semiconductor layer at least at a peripheral edge of the second-conductivity type semiconductor layer; a first electrode electrically connected to the first-conductivity type semiconductor layer; a second electrode provided nearer to the first-conductivity type semiconductor layer than the second-conductivity type semiconductor layer; and a conductor electrically connecting the second electrode and the contact layer to each other.

Abstract: By using a light emitting device including an insulating substrate and a light emitting unit formed on the insulating substrate, the light emitting unit including: a plurality of linear wiring patterns disposed on the insulating substrate in parallel with one another, a plurality of light emitting elements that are mounted between the wiring patterns while being electrically connected to the wiring patterns, and a sealing member for sealing the light emitting elements, as well as a method for manufacturing thereof, it becomes possible to provide a light emitting device that achieves sufficient electrical insulation and has simple manufacturing processes so that it can be manufactured at a low cost, and a method for manufacturing the same.

Abstract: An LED module includes: a package having electrodes provided on the outer surface of opposing sidewalls, and a light-emitting element connected to the electrodes and mounted on the package; a base member having a copper metal; an insulating layer stacked on the surface of the base member and having an insulating material; and a conductive wiring pattern connected to the electrodes by soldering and formed on the surface of the insulating layer. The insulating layer has a through-hole formed by removing a part of the section where the package is positioned, and a heat dissipation unit formed by soldering between the back surface of the package and the base member, which face one another with the through-hole interposed therebetween.

Abstract: A semiconductor device includes a semiconductor layer; a first type of a first semiconductor element that is arranged in a first element region of the semiconductor layer, has first and second main electrodes, and switches current; and a second type of a second semiconductor element that is arranged in a second element region of the semiconductor layer, has third and fourth main electrodes, and freewheels the current. The first and second element regions are adjacent in a direction orthogonal to a direction in which current flows, and are formed in a loop shape over the entire element region when the semiconductor layer is viewed from above. The first main electrode is electrically connected to the third main electrode, and the second main electrode is electrically connected to the fourth main electrode.

Abstract: The present invention discloses a semiconductor structure and a manufacturing method thereof. The semiconductor structure is formed in a first conductive type substrate, which has an upper surface. The semiconductor structure includes: a protected device, at least a buried trench, and at least a doped region. The protected device is formed in the substrate. The buried trench is formed below the upper surface with a first depth, and the buried trench surrounds the protected device from top view. The doped region is formed below the upper surface with a second depth, and the doped region surrounds the buried trench from top view. The second depth is not less than the first depth.

Abstract: In a semiconductor device having a semiconductor substrate on which a diode and an IGBT are formed, a cathode region of the diode and a collector region of the IGBT are formed in a range exposed to one surface of the semiconductor substrate. On the surface, a first conductor layer that is in contact with the cathode region, and a second conductor layer that is in contact with the collector region are formed. The work function of the second conductor layer is larger than the work function of the first conductor layer.

Abstract: There is provided a vertical GaN-based semiconductor device in which the on-resistance can be decreased while the breakdown voltage characteristics are improved using a p-type GaN barrier layer. The semiconductor device includes a regrown layer 27 including a channel located on a wall surface of an opening 28, a p-type barrier layer 6 whose end face is covered, a source layer 7 that is in contact with the p-type barrier layer, a gate electrode G located on the regrown layer, and a source electrode S located around the opening. In the semiconductor device, the source layer has a superlattice structure that is constituted by a stacked layer including a first layer (a layer) having a lattice constant smaller than that of the p-type barrier layer and a second layer (b layer) having a lattice constant larger than that of the first layer.

Abstract: In an embodiment, a semiconductor device is provided. The semiconductor device may include a substrate having a main processing surface, a first source/drain region comprising a first material of a first conductivity type, a second source/drain region comprising a second material of a second conductivity type, wherein the second conductivity type is different from the first conductivity type, a body region electrically coupled between the first source/drain region and the second source/drain region, wherein the body region extends deeper into the substrate than the first source/drain region in a first direction that is perpendicular to the main processing surface of the substrate, a gate dielectric disposed over the body region, and a gate region disposed over the gate dielectric, wherein the gate region overlaps with at least a part of the first source/drain region and with a part of the body region in the first direction.

Abstract: A semiconductor die includes at least one flexible interface block. The flexible interface block includes at least one interconnect, and at least one buffer coupled to the at least one interconnect. The flexible interface block further includes a routing interface coupled to circuitry integrated in the semiconductor die, and a controller coupled to provide communication between the routing interface and the at least one buffer.

Abstract: An image sensor includes a substrate having opposite first and second sides, a multilayer structure on the first side of the substrate, and a photo-sensitive element on the second side of the substrate. The photo-sensitive element is configured to receive light that is incident upon the first side and transmitted through the multilayer structure and the substrate. The multilayer structure includes first and second light transmitting layers. The first light transmitting layer is sandwiched between the substrate and the second light transmitting layer. The first light transmitting layer has a refractive index that is from 60% to 90% of a refractive index of the substrate. The second light transmitting layer has a refractive index that is lower than the refractive index of the first light transmitting layer and is from 40% to 70% of the refractive index of the substrate.

Abstract: Interlayer dielectric gap fill processes are enhanced by forming gate spacers with a step-like or tapered profile. Embodiments include forming a gate electrode on a substrate, depositing a spacer material over the gate electrode, etching the spacer material to form a first spacer on each side of the gate electrode, and pulling back the first spacers to form second spacers which have a step-like profile. Embodiments further include depositing a second spacer material over the gate electrode and the second spacers, and etching the second spacer material to form a third spacer on each second spacer, the second and third spacers forming an outwardly tapered composite spacer.

Abstract: Semiconductor devices with n-shaped bottom stress liners are formed. Embodiments include forming a protuberance on a substrate, conformally forming a sacrificial material layer over the protuberance, forming a gate stack above the sacrificial material layer on a silicon layer, removing the sacrificial material layer to form a tunnel, and forming a stress liner in the tunnel conforming to the shape of the protuberance. Embodiments further include forming a silicon layer over the sacrificial material layer and lining the tunnel with a passivation layer prior to forming the stress liner.

Abstract: A borderless contact structure or partially borderless contact structure and methods of manufacture are disclosed. The method includes forming a gate structure and a space within the gate structure, defined by spacers. The method further includes blanket depositing a sealing material in the space, over the gate structure and on a semiconductor material. The method further includes removing the sealing material from over the gate structure and on the semiconductor material, leaving the sealing material within the space. The method further includes forming an interlevel dielectric material over the gate structure. The method further includes patterning the interlevel dielectric material to form an opening exposing the semiconductor material and a portion of the gate structure. The method further includes forming a contact in the opening formed in the interlevel dielectric material.

Abstract: A method includes forming a gate stack over a semiconductor substrate, wherein the gate stack includes a gate dielectric and a gate electrode over the gate dielectric. A portion of the semiconductor substrate adjacent to the gate stack is recessed to form a recess. A semiconductor region is epitaxially grown in the recess. The semiconductor region is implanted with a p-type impurity or an n-type impurity. A dry treatment is performed on the semiconductor region.

Abstract: Disclosed herein are various methods of forming isolation structures on FinFETs and other semiconductor devices, and the resulting devices that have such isolation structures. In one example, the method includes forming a plurality of spaced-apart trenches in a semiconducting substrate, wherein the trenches define a fin for a FinFET device, forming a layer of insulating material in the trenches, wherein the layer of insulating material covers a lower portion of the fin but not an upper portion of the fin, forming a protective material on the upper portion of the fin, and performing a heating process in an oxidizing ambient to form a thermal oxide region on the covered lower portion of the fin.

Abstract: A semiconductor structure includes at least a fin-shaped structure, a gate, a source/drain region, an interdielectric layer and an epitaxial structure. At least a fin-shaped structure is located on a bottom substrate. The gate covers the fin-shaped structure. The source/drain region is located in the fin-shaped structure next to the gate. The interdielectric layer covers the gate and the fin-shaped structure, wherein the interdielectric layer has a plurality of contact holes, respectively exposing at least a part of the source/drain region. The epitaxial structure is located in each of the contact holes, directly contacts and is only located on the source/drain region. Additionally, a semiconductor process formed said semiconductor structure is also provided.

Abstract: Disclosed herein are various methods of forming a gate cap layer above a replacement gate structure, and a device having such a cap layer. In one example, a device disclosed herein includes a replacement gate structure having a dished upper surface, sidewall spacers positioned proximate the replacement gate structure and a gate cap layer positioned above the replacement gate structure, wherein the gate cap layer has a bottom surface that corresponds to the dished upper surface of the replacement gate structure.

Abstract: In a method of fabricating a semiconductor device on a substrate having thereon a conductive layer, the conductive layer is patterned to form a plurality of opened regions. A gate insulation layer is formed on a side wall of each of the opened regions. A pillar pattern is formed in each opened region. On each pillar pattern, a gate electrode, which encloses the pillar pattern, is formed by removing the conductive layer between the pillar patterns.

Abstract: A semiconductor device includes an active region including an element formed in a double etch, double exposure method and an inactive region including one or more fills, at least one of the one or more fills including a cut-away hole formed therein, where the cut-away holes expose a layer in the inactive region used for an endpoint detection.

Abstract: A photoelectric conversion section contains a semiconductor element having a laminated structure which contains an electroconductor, a semiconductor, and an insulator provided between the electroconductor and the semiconductor, in which the insulator is a silicon oxide film containing nitrogen in a main portion located between the electroconductor and the semiconductor.

Abstract: A device comprises a semiconductor substrate having first and second implant regions and an electrode above and between the first and second implant regions of a first dopant type. A contact structure is in direct contact with the first and second implant regions and the electrode. A third implant region has a second dopant type different from the first dopant type. A bulk contact is provided on the third implant.

Abstract: A semiconductor device includes a capacitor, the capacitor includes: a first semiconductor region of a first conductivity type; a second semiconductor region of the first conductivity type disposed on the first semiconductor region, the second semiconductor region having a higher first-conductivity-type impurity concentration than the first semiconductor region; a third semiconductor region of the first conductivity type disposed on the second semiconductor region, the third semiconductor region including a contact region and having a higher first-conductivity-type impurity concentration than the second semiconductor region; a dielectric film disposed on the third semiconductor region; and an upper electrode disposed on the dielectric film beside the contact region.