Abstract: In accordance with certain embodiments, illumination systems are formed by aligning light-emitting elements with optical elements and/or disposing light-conversion materials on the light-emitting elements, as well as by providing electrical connectivity to the light-emitting elements

Abstract: A light emitter includes a first mirror that is an epitaxially grown metal mirror, a second mirror, and an active region that is epitaxially grown such that the active region is positioned at or close to, at least, one antinode between the first mirror and the second mirror.

Abstract: A nitride-based semiconductor light emitting device with improved characteristics of ohmic contact to an n-electrode and a method of fabricating the same are provided. The nitride-based semiconductor light emitting device includes an n-electrode, a p-electrode, an n-type compound semiconductor layer, and an active layer and a p-type compound semiconductor layer formed between the n- and p-electrodes. The n-electrode includes: a first electrode layer formed of at least one element selected from the group consisting of Pd, Pt, Ni, Co, Rh, Ir, Fe, Ru, Os, Cu, Ag, and Au; and a second electrode layer formed on the first electrode layer using a conductive material containing at least one element selected from the group consisting of Ti, V, Cr, Zr, Nb, Hf, Ta, Mo, W, Re, Ir, Al, In, Pb, Ni, Rh, Ru, Os, and Au.

Abstract: A semiconductor light emitting device has a support substrate, a light emitting element, and underfill material. The light emitting element includes a nitride-based group III-V compound semiconductor layer contacted via a bump on the support substrate. The underfill material is disposed between the support substrate and the light emitting element, the underfill material comprising a rib portion disposed outside of an end face of the light emitting element to surround the end surface of the light emitting element.

Abstract: The present invention provides: an epitaxial film forming method capable of fabricating a +c-polarity epitaxial film made of a Group III nitride semiconductor by sputtering; and a vacuum processing apparatus suitable for this epitaxial film forming method. In one embodiment of the present invention, a Group III nitride semiconductor thin film is epitaxially grown by sputtering on an ?-Al2O3 substrate heated to a desired temperature by using a heater. First, the ?-Al2O3 substrate is disposed on a substrate holder including the heater in such a way that the ?-Al2O3 substrate is disposed away from the heater by a predetermined distance. Then, an epitaxial film of a Group III nitride semiconductor thin film is formed on the ?-Al2O3 substrate in the state where the ?-Al2O3 substrate is disposed away from the heater by the predetermined distance.

Abstract: The present invention provides a method of fabricating a vertical type light-emitting diode and a method of separating layers from each other. Crystalline rods are provided on a lower layer or a lower substrate. The crystalline rods comprise ZnO. A layer which constitutes light-emitting diode or a light-emitting diode structure is formed on the crystalline rods, and the lower substrate is separated therefrom. The crystalline rods are dissolved during the separation.

Abstract: One or more layers are epitaxially grown on a bulk crystalline AlN substrate. The epitaxial layers include a surface which is the initial surface of epitaxial growth of the epitaxial layers. The AlN substrate is substantially removed over a majority of the initial surface of epitaxial growth.

Abstract: Gold is used as a micromask to roughen a gallium nitride (GaN) surface in an LED device. In one example, a mesh of ITO (Indium Tin Oxide) is formed on a GaN layer. The mesh has holes that extend down to the GaN. A layer of silicon dioxide is deposited so that it covers the GaN at the bottoms of the holes. A layer of gold is formed over the oxide. A thermal treatment causes the gold to ball up into small gold features. These gold features are used as a micromask in a subsequent etching step. Areas of the bottoms of the holes that are not covered by a gold feature are etched. Etching occurs through the oxide and down into the GaN. The roughening process involves no silver, and involves no harsh cleaning solvents or processes that might otherwise have been used were the micromask made of silver.

Abstract: A light-emitting device and method for manufacturing the same are described. A method for manufacturing a light-emitting device comprising steps of: providing a growth substrate, wherein the growth substrate has a first surface and a second surface; forming a light-absorbable layer on the first surface of the growth substrate; forming an illuminant epitaxial structure on the light absorbable layer; providing a laser beam and irradiating the second surface of the growth substrate, wherein the laser beam wavelength is greater than 1000 nm; and removing the growth substrate.

Abstract: The invention provides a compound semiconductor light-emitting element including: a substrate on which an n-type semiconductor layer (12), a light-emitting layer (13), and a p-type semiconductor layer (14) that are made of a compound semiconductor are stacked in this order; a positive electrode (15) made of a conductive translucent electrode; and a negative electrode (17) made of a conductive electrode, wherein the conductive translucent electrode of the positive electrode (15) is a transparent conductive film containing crystals composed of In2O3 having a hexagonal crystal structure.

Abstract: A method for producing a Group III nitride semiconductor light-emitting device includes forming a first stripe-pattern embossment on the top surface of a sapphire substrate, so that first grooves parallel to the x-axis direction (the c-axis direction of the sapphire substrate) are periodically arranged at specific intervals. Subsequently, an insulating film is formed over the entire surface of the first stripe-pattern embossment. Next, a second stripe-pattern embossment is formed so that second grooves, each having a flat bottom surface, are periodically arranged at specific intervals and parallel to the y-axis direction, which is orthogonal to the x-axis direction. A GaN crystal is grown through MOCVD on side surfaces of each second groove of the sapphire substrate, to thereby form, on the sapphire substrate, an m-plane GaN base layer. An LED device structure is formed on the base layer, to thereby produce a light-emitting device.

Abstract: A light emitting device includes a substrate, multiple n-type layers, and multiple p-type layers. The n-type layers and the p-type layers each include a group III nitride alloy. At least one of the n-type layers is a compositionally graded n-type group III nitride, and at least one of the p-type layers is a compositionally graded p-type group III nitride. A first ohmic contact for injecting current is formed on the substrate, and a second ohmic contact is formed on a surface of at least one of the p-type layers. Utilizing the disclosed structure and methods, a device capable of emitting light over a wide spectrum may be made without the use of phosphor materials.

Abstract: The present invention discloses a LED structure and a method for manufacturing the LED structure. The LED structure includes a substrate, a reflection layer, a first conducting layer, a light emitting layer, and a second conducting layer. The substrate has a plurality of grooves, and the reflection layer is disposed inside the plurality of grooves. The reflection layer is formed as a reflection block inside each of the grooves. The first conducting layer is disposed on the substrate, that is, the reflection layer is disposed between the first conducting layer and the substrate. The light emitting layer and the second conducting layer are sequentially disposed on the first conducting layer. The light emitting layer generates light when a current pass through the light emitting layer. Accordingly, the light generated by the light emitting layer can be emitted to the same side of the LED structure.

Abstract: A method for forming a plurality of semiconductor light emitting devices includes forming an epitaxial layer having a first type doped layer, a light emitting layer, and a second type doped layer on a first temporary substrate. The epitaxial layer is separated into a plurality of epitaxial structures on the first temporary substrate. A second temporary substrate is coupled to the epitaxial layer with a first adhesive layer and the first temporary substrate is removed from the epitaxial layer. A permanent semiconductor substrate is coupled to the epitaxial layer with a second adhesive layer. The second temporary substrate and the first adhesive layer are removed from the epitaxial layer. The permanent semiconductor substrate is separated into a plurality of portions with each portion corresponding to at least one of the plurality of epitaxial structures to form a plurality of semiconductor light emitting devices.

Abstract: Disclosed is a photoelectric conversion device which inhibits characteristic degradation caused by crystal defects, and an inspection method for crystal defects in photoelectric conversion devices. The photoelectric conversion device is provided with an active layer, and a deactivator contained in the active layer.

Abstract: A method for growing III-V nitride films having an N-face or M-plane using an ammonothermal growth technique. The method comprises using an autoclave, heating the autoclave, and introducing ammonia into the autoclave to produce smooth N-face or M-plane Gallium Nitride films and bulk GaN.

Abstract: A nitride semiconductor light emitting element has; a laminate of a first conduction type semiconductor layer, a light emitting layer and a second conduction type semiconductor layer of a different conduction type from that of the first conduction type semiconductor layer; and electrodes with a laminate structure formed on the first conduction type semiconductor layer, the electrodes include a conductive region of a first layer which has the conductive region and an insulated region.

Abstract: Provided is a nitride semiconductor light emitting device including p-type nitride semiconductor layer, an n-type nitride semiconductor layer, and an active layer formed therebetween. A contact layer is positioned between the p-type nitride semiconductor layer and a p-side electrode. The contact layer includes a first p-type nitride layer having a first impurity concentration to form ohmic contact with the p-side electrode and a second p-type nitride layer having a second impurity concentration, the second impurity concentration having a concentration lower than the first impurity concentration.

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 light emitting diode is provided which includes an active region in combination with a current spreading layer; and a crystalline epitaxial film light extraction layer in contact with the current spreading layer, the light extraction layer being patterned with nano/micro structures which increase extraction of light emitted from the active region.

Abstract: A laterally contacted blue LED device involves a PAN structure disposed over an insulating substrate. The substrate may be a sapphire substrate that has a template layer of GaN grown on it. The PAN structure includes an n-type GaN layer, a light-emitting active layer involving indium, and a p-type GaN layer. The n-type GaN layer has a thickness of at least 500 nm. A Low Resistance Layer (LRL) is disposed between the substrate and the PAN structure such that the LRL is in contact with the bottom of the n-layer. In one example, the LRL is an AlGaN/GaN superlattice structure whose sheet resistance is lower than the sheet resistance of the n-type GnA layer. The LRL reduces current crowding by conducting current laterally under the n-type GaN layer. The LRL reduces defect density by preventing dislocation threads in the underlying GaN template from extending up into the PAN structure.

Abstract: A nitride-based semiconductor light-emitting device 100 includes a GaN substrate 10, of which the principal surface is an m-plane 12, a semiconductor multilayer structure 20 that has been formed on the m-plane 12 of the GaN-based substrate 10, and an electrode 30 arranged on the semiconductor multilayer structure 20. The electrode 30 includes an Mg alloy layer 32 which is formed of Mg and a metal that makes an alloy with Mg less easily than Au. The Mg alloy layer 32 is in contact with a surface of a p-type semiconductor region of the semiconductor multilayer structure 20.

Abstract: A nitride semiconductor light emitting device includes a conductive substrate, a first metal layer, a second conductivity-type semiconductor layer, an emission layer, and a first conductivity-type semiconductor layer in this order. The nitride semiconductor light emitting device additionally has an insulating layer covering at least side surfaces of the second conductivity-type semiconductor layer, the emission layer and the first conductivity-type semiconductor layer. A method of manufacturing the same is provided. The nitride semiconductor light emitting device may further include a second metal layer. Thus, a reliable nitride semiconductor light emitting device and a method of manufacturing the same are provided in which short-circuit at the PN junction portion and current leak is reduced as compared with the conventional examples.

Abstract: An LED comprises a substrate, a buffer layer, an epitaxial layer and a conductive layer. The epitaxial layer comprises a first N-type epitaxial layer, a second N-type epitaxial layer, and a blocking layer with patterned grooves sandwiched between the first and second N-type epitaxial layers. The first and second N-type epitaxial layers make contact each other via the patterned grooves. Therefore, the LED enjoys a uniform current distribution and a larger light emitting area. A manufacturing method for the LED is also provided.

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: An MQW-structure light-emitting layer is formed by alternately stacking InGaN well layers and AlGaN barrier layers. Each well layer and each barrier layer are formed so as to satisfy the following relations: 12.9??2.8x+100y?37 and 0.65?y?0.86, or to satisfy the following relations: 162.9?7.1x+10z?216.1 and 3.1?z?9.2, here x represents the Al compositional ratio (mol %) of the barrier layer, and y represents the difference in bandgap energy (eV) between the barrier layer and the well layer, and z represents the In compositional ratio (mol %) of the well layer.

Abstract: The present invention relates to a multi-luminous element and a method for manufacturing the same. The present invention provides the multi-luminous element comprising: a buffer layer disposed on a substrate; a first type semiconductor layer disposed on the buffer layer; a first active layer which is disposed on the first type semiconductor layer and is patterned to expose a part of the first type semiconductor layer; a second active layer disposed on the first type semiconductor layer which is exposed by the first active layer; and a second type semiconductor layer disposed on the first active layer and the second active layer, the first and second active layers being repeatedly disposed in the horizontal direction, and the method for manufacturing the same.

Abstract: There is provided a method of manufacturing a semiconductor light emitting device, the method including: sequentially growing a first conductivity type semiconductor layer, an active layer, and a second conductivity type semiconductor layer on a semiconductor growth substrate to form a light emitting part; forming a support part on the second conductivity type semiconductor layer to be coupled to the light emitting part; separating the semiconductor growth substrate from the light emitting part; and applying an etching gas to the semiconductor growth substrate to remove a residue of the first conductivity type semiconductor layer from a surface of the semiconductor growth substrate.

Abstract: Provided is a method for manufacturing a nitride semiconductor device, including the steps of: forming an AlNO buffer layer containing at least aluminum, nitrogen, and oxygen on a substrate; and forming a nitride semiconductor layer on the AlNO buffer layer, wherein, in the step of forming the AlNO buffer layer, the AlNO buffer layer is formed by a reactive sputtering method using aluminum as a target in an atmosphere to and from which nitrogen gas and oxygen gas are continuously introduced and exhausted, and the atmosphere is an atmosphere in which a ratio of a flow rate of the oxygen gas to a sum of a flow rate of the nitrogen gas and the flow rate of the oxygen gas is not more than 0.5%.

Abstract: Provided are a light emitting device and a method of fabricating the same. The light emitting device comprises: a first conductive semiconductor layer; an active layer comprising an InGaN well layer and a GaN barrier layer on the first conductive semiconductor layer; and a second conductive semiconductor layer on the active layer. The GaN barrier layer comprises an AlGaN layer.

Abstract: A device and method for making the same are disclosed. The device includes a substrate having a first TEC, a stress relief layer overlying the substrate, and crystalline cap layer. The crystalline cap layer overlies the stress relief layer. The cap layer has a second TEC different from the first TEC. The stress relief layer includes an amorphous material that relieves stress between the crystalline substrate and the cap layer arising from differences in the first and second TECs at a growth temperature at which layers are grown epitaxially on the cap layer. The device can be used to construct various semiconductor devices including GaN LEDs that are fabricated on silicon or SiC wafers. The stress relief layer is generated by converting a layer of precursor material on the substrate after the cap layer has been grown to a stress-relief layer.

Abstract: A light emitting diode and a fabricating method thereof are provided. A first-type semiconductor layer, a light emitting layer and a second-type semiconductor layer with a first surface are sequentially formed a substrate. Next, the first surface is treated during a surface treatment process to form a current-blocking region which extends from the first surface to the light emitting layer to a depth of 1000 angstroms. Afterward, a first electrode is formed above the current-blocking region of the second-type semiconductor layer, and a second electrode is formed to electrically contact to the first-type semiconductor layer. Since the current-blocking region is formed with a determined depth within the second-type semiconductor layer, the light extraction efficiency of the light emitting diode may be increased.

Abstract: A compound semiconductor light-emitting element characterized by high transmittance of an electrically conductive film, low contact resistance and low sheet resistance of electrically conductive film is manufactured. The manufacturing method for a compound semiconductor light-emitting element of the present invention includes the steps of: forming a semiconductor layer formed of a group III nitride semiconductor, including a light-emitting layer on a substrate; forming an electrically conductive film on the side of the semiconductor layer opposite to the side contacting the substrate; conducting first annealing on the electrically conductive film in an atmosphere containing oxygen; conducting second annealing on the electrically conductive film in an atmosphere not containing oxygen; and exposing the electrically conductive film to atmospheric air between the step of conducting first annealing and the step of conducting second annealing.

Abstract: A light emitting diode structure of (Al,Ga,In)N thin films grown on a gallium nitride (GaN) semipolar substrate by metal organic chemical vapor deposition (MOCVD) that exhibits reduced droop. The device structure includes a quantum well (QW) active region of two or more periods, n-type superlattice layers (n-SLs) located below the QW active region, and p-type superlattice layers (p-SLs) above the QW active region. The present invention also encompasses a method of fabricating such a device.

Abstract: The method for producing a group III nitride semiconductor crystal comprises preparing a seed crystal having a non-polar plane followed by growing a group III nitride semiconductor from the non-polar plane in a vapor phase, wherein the growing includes growing the group III nitride semiconductor so as to extend in the +C-axis direction of the seed crystal. A group III-V nitride semiconductor crystal having high quality and a large-area non-polar plane can be obtained by the method.

Abstract: An epitaxial substrate includes: a base member; and a plurality of spaced apart light-transmissive members, each of which is formed on and tapers from an upper surface of the base member, and each of which is made of a light-transmissive material having a refractive index lower than that of the base member. A light-emitting diode having the epitaxial substrate, and methods for making the epitaxial substrate and the light-emitting diode are also disclosed.

Abstract: Various embodiments of light emitting devices with built-in chromaticity conversion and associated methods of manufacturing are described herein. In one embodiment, a method for manufacturing a light emitting device includes forming a first semiconductor material, an active region, and a second semiconductor material on a substrate material in sequence, the active region being configured to produce a first emission. A conversion material is then formed on the second semiconductor material. The conversion material has a crystalline structure and is configured to produce a second emission. The method further includes adjusting a characteristic of the conversion material such that a combination of the first and second emission has a chromaticity at least approximating a target chromaticity of the light emitting device.

Abstract: Surface passivation techniques for chamber-split processing are described. A method includes forming a first Group III-V material layer above a substrate, the first Group III-V material layer having a top surface. A passivation layer is deposited on the top surface of the Group III-V material layer. The passivation layer is removed. Subsequently, a second Group III-V material layer is formed above the first Group III-V material layer.

Abstract: According to one embodiment, a nitride semiconductor device includes a foundation layer and the functional layer. The foundation layer is formed on an amorphous layer and includes aluminum nitride. The functional layer is formed on the foundation layer and includes a nitride semiconductor.

Abstract: Disclosed is a method of producing a semiconductor wafer, which includes: placing a wafer (10), which is provided with a substrate (11) and a semiconductor layer (20) formed on the substrate (11), on a carrier plate (fixing plate) (31) of a grinder via fixing wax (33a and 33b) in a manner such that the surface (10a) to be ground of the wafer (10) faces upward; heating the carrier plate (31), on which the wafer (10) is placed, in order to soften the fixing wax (33a and 33b); pressure-contacting the wafer (10) from the side of the surface (10a) to be ground by means of an air bag in a manner such that a portion of the softened fixing wax (33a and 33b) spreads and protrudes from the peripheral edge of the wafer (10); cooling the carrier plate (31) while applying pressure to the wafer (10) in order to cure the fixing wax (33a and 33b) and fix the wafer (10) onto the carrier plate (31); and rotating the surface (10a) to be ground of the fixed wafer (10) while pressure-contacting the surface (10a) to the grinding p

Abstract: A method for producing a light-emitting device including a growth substrate made of Group III nitride semiconductor, and a Group III nitride semiconductor layer stacked on the top surface of the growth substrate, includes forming, between the growth substrate and the semiconductor layer, a stopper layer exhibiting resistance to a wet etchant, and wet-etching the bottom surface of the growth substrate until the stopper layer is exposed.

Abstract: Provided are a semiconductor light emitting device and a method of manufacturing the same. The semiconductor light emitting device comprises a first conductive type semiconductor layer, an active layer, a first thin insulating layer, and a second conductive type semiconductor layer. The active layer is formed on the first conductive type semiconductor layer. The first thin insulating layer is formed on the active layer. The second conductive type semiconductor layer is formed on the thin insulating layer.

Abstract: A Group-III nitride optoelectronic device fabricated on a semipolar (20-2-1) plane of a Gallium Nitride (GaN) substrate is characterized by a high Indium uptake and a high polarization ratio.

Abstract: A III-nitride light emitting device having a substrate with a conductive grid made of conductive lines formed thereon. An active-region is sandwiched between an n-type layer and a p-type layer forming an LED structure, and the conductive grid is in ohmic contact with the n-type layer. Also provided is a method for fabricating the same.

Abstract: An epitaxial wafer for a light emitting diode (LED) and a method for manufacturing the same are provided. The method comprises: providing a substrate; forming a first LED epitaxial structure on a first surface of the substrate, in which the first LED epitaxial structure comprises a first n-type semiconductor layer, a first light emitting layer, a first anti-diffusion layer between the first n-type semiconductor layer and the first light emitting layer, a first p-type semiconductor layer, and a second anti-diffusion layer between the first p-type semiconductor layer and the first light emitting layer; and forming a second LED epitaxial structure on a second surface of the substrate. An LED chip comprising the epitaxial wafer and a method for manufacturing the same are also provided.

Abstract: A Group III nitride semiconductor laser device includes a laser structure including a support substrate with a semipolar primary surface of a hexagonal Group III nitride semiconductor, and a semiconductor region thereon, and an electrode, provided on the semiconductor region, extending in a direction of a waveguide axis in the laser device. The c-axis of the nitride semiconductor is inclined at an angle ALPHA relative to a normal axis to the semipolar surface toward the waveguide axis direction. The laser structure includes first and second fractured faces intersecting with the waveguide axis. A laser cavity of the laser device includes the first and second fractured faces extending from edges of first and second faces. The first fractured face includes a step provided at an end face of an InGaN layer of the semiconductor region and extending in a direction from one side face to the other of the laser device.

Abstract: A method of fabricating semiconductor devices, such as GaN LEDs, on insulating substrates, such as sapphire. Semiconductor layers are produced on the insulating substrate using normal techniques. Trenches that define the boundaries of the individual devices are formed through the semiconductor layers and into the insulating substrate, beneficially by inductive coupled plasma reactive ion etching. A first support structure is attached to the semiconductor layers. The hard substrate is then removed, beneficially by laser lift off. A second supporting structure, preferably conductive, is substituted for the hard substrate and the first supporting structure is removed. Individual devices are then diced, beneficially by etching through the second supporting structure. A protective photo-resist layer can protect the semiconductor layers from the attachment of the first support structure.

Abstract: Affords a GaN single-crystal mass, a method of its manufacture, and a semiconductor device and method of its manufacture, whereby when the GaN single-crystal mass is being grown, and when the grown GaN single-crystal mass is being processed into a substrate or like form, as well as when an at least single-lamina semiconductor layer is being formed onto a single-crystal GaN mass in substrate form to manufacture semiconductor devices, cracking is controlled to a minimum. The GaN single-crystal mass 10 has a wurtzitic crystalline structure and, at 30° C., its elastic constant C11 is from 348 GPa to 365 GPa and its elastic constant C13 is from 90 GPa to 98 GPa; alternatively its elastic constant C11 is from 352 GPa to 362 GPa.

Abstract: The purpose of the present invention is to obtain a nitride-based semiconductor light emitting element capable of improving light emission efficiency by reducing sheet resistance and a forward voltage of a translucent electrode including indium cerium oxide. The nitride-based semiconductor light emitting element of the present invention is has a translucent electrode including indium cerium oxide; and cerium oxide is contained in a ratio of 10 to 20 wt % with respect to a whole of the indium cerium oxide.

Abstract: The present disclosure provides one embodiment of a light-emitting structure. The light-emitting structure includes a carrier substrate having first metal features; a transparent substrate having second metal features; a plurality of light-emitting diodes (LEDs) bonded with the carrier substrate and the transparent substrate, sandwiched between the carrier substrate and the transparent substrate; and metal pillars bonded to the carrier substrate and the transparent substrate, each of the metal pillars being disposed between adjacent two of the plurality of LEDs, wherein the first metal features, the second metal features and the metal pillars are configured to electrically connect the plurality of LEDs.