| Class / Patent application number | Description | Number of patent applications / Date published |
|---|
| 438031000 | Optical waveguide structure | 57 |
| 20120244654 | ENHANCED PLANARITY IN GaN EDGE EMITTING LASERS - A GaN edge emitting laser is provided comprising a semi-polar GaN substrate, an active region, N-side and P-side waveguiding layers, and N-type and P-type cladding layers. The GaN substrate defines a 20 | 09-27-2012 |
| 20130034922 | VERTICAL CAVITY SURFACE EMITTING LASER, VERTICAL CAVITY SURFACE EMITTING LASER DEVICE, OPTICAL TRANSMISSION DEVICE, AND INFORMATION PROCESSING APPARATUS - A vertical cavity surface emitting laser that includes: a substrate; a first semiconductor multilayer reflector; an active region; a second semiconductor multilayer reflector; a columnar structure formed from the second semiconductor multilayer reflector to the first semiconductor multilayer reflector; a current narrowing layer formed inside of the columnar structure and having a conductive region surrounded by an oxidization region; a first electrode formed at a top of the columnar structure, electrically connected to the second semiconductor multilayer reflector and defining a beam window; a first insulating film comprised of a material with a first refractive index and formed on the first electrode to cover the beam window; and a second insulating film comprised of a material with a second refractive index and formed on the first insulating film, of which a radius is smaller than a radius of the conductive region. | 02-07-2013 |
| 20100015741 | FABRICATION PROCESS FOR SILICON RIDGE WAVEGUIDE RING RESONATOR - An embodiment of a method for manufacturing an optical ring resonator device is disclosed. The method forms a ring resonator waveguide on a semiconductor substrate, forms an unoriented electro-optic polymer cladding over the ring resonator waveguide, and forms electrodes on the semiconductor substrate. The unoriented electro-optic polymer cladding is configured to change orientation under an applied electric field, and the electrodes are coupled to the optical ring resonator for manipulation of the electric field applied to the oriented electro-optic polymer cladding for rapid voltage tuning of its index. | 01-21-2010 |
| 20110281382 | NITRIDE-BASED SEMICONDUCTOR DEVICE AND METHOD OF FABRICATING THE SAME - A nitride-based semiconductor device includes a substrate constituted by nitride-based semiconductor, a nitride-based semiconductor layer formed on the substrate and constituted by nitride-based semiconductor, formed with a light waveguide extending in a first direction, and first step portions formed at least on regions other than the vicinity of facets of the light waveguide from a surface opposite to a side where the nitride-based semiconductor layer of the substrate is formed along the first direction in which the light waveguide extends. | 11-17-2011 |
| 20090311815 | MULTI-WAVELENGTH INTEGRATED SEMICONDUCTOR LASER DEVICE AND METHOD FOR MANUFACTURING SAME - An object is to provide a multi-wavelength integrated semiconductor laser device which can reduce variations in emission point distance, can be formed by simplified manufacturing processes, and can provide improve electric characteristics. | 12-17-2009 |
| 20100144075 | METHOD OF FORMING OPTICAL WAVEGUIDE - Provided is a method of forming optical waveguide. The method includes forming a trench on a semiconductor substrate to define an active portion, and partially oxidizing the active portion. An non-oxidized portion of the active portion is included in a core through which an optical signal passes, and an oxidized portion of the active portion is included in a cladding. | 06-10-2010 |
| 20100003777 | Quantum Photonic Imagers and Methods of Fabrication Thereof - Emissive quantum photonic imagers comprised of a spatial array of digitally addressable multicolor pixels. Each pixel is a vertical stack of multiple semiconductor laser diodes, each of which can generate laser light of a different color. Within each multicolor pixel, the light generated from the stack of diodes is emitted perpendicular to the plane of the imager device via a plurality of vertical waveguides that are coupled to the optical confinement regions of each of the multiple laser diodes comprising the imager device. Each of the laser diodes comprising a single pixel is individually addressable, enabling each pixel to simultaneously emit any combination of the colors associated with the laser diodes at any required on/off duty cycle for each color. Each individual multicolor pixel can simultaneously emit the required colors and brightness values by controlling the on/off duty cycles of their respective laser diodes. | 01-07-2010 |
| 20080311693 | Method of Aligning Optical Components With Waveguides - A method of fabricating a photonic device comprises the steps of providing a core pattern of waveguide core material ( | 12-18-2008 |
| 20100087022 | SEMICONDUCTOR LASER, METHOD OF MANUFACTURING SEMICONDUCTOR LASER, OPTICAL PICKUP AND OPTICAL DISK SYSTEM - A semiconductor laser using a nitride type Group III-V compound semiconductor includes: an n-side clad layer; an n-side optical waveguide layer over the n-side clad layer; an active layer over the n-side optical waveguide layer; a p-side optical waveguide layer over the active layer; an electron barrier layer over the p-side optical waveguide layer; and a p-side clad layer over the electron barrier layer. A ridge stripe is formed at an upper part of the p-side optical waveguide layer, the electron barrier layer and the p-side clad layer, and the distance between the electron barrier layer and a bottom surface in areas on both sides of the ridge stripe is not less than 10 nm. | 04-08-2010 |
| 20090239323 | Microresonator Systems And Methods Of Fabricating The Same - Various embodiments of the present invention are related to microresonator systems and to methods for fabricating the microresonator systems. In one embodiment, a method of fabricating a microresonator system comprises: forming a multilayer system having a bottom layer, a top layer, and an intermediate layer having one or more quantum wells and sandwiched between the bottom layer and the top layer; embedding at least one waveguide in a substrate having a top surface, the at least one waveguide positioned adjacent to the top surface of the substrate; wafer bonding the top layer of the multilayer system to the top surface of the substrate; forming a microresonator in the multilayer system, wherein at least a portion of a peripheral annular region of the microresonator is portioned above the at least one waveguide; and forming a current isolation region in at least a portion of a central region of the microresonator. | 09-24-2009 |
| 20090263923 | SEMICONDUCTOR DEVICE USING BURIED OXIDE LAYER AS OPTICAL WAVE GUIDES - A semiconductor optical wave guide device is described in which a buried oxide layer (BOX) is capable of guiding light. Optical signals may be transmitted from one part of the semiconductor device to another, or with a point external to the semiconductor device, via the wave guide. In one example, an optical wave guide is provided including a core insulating layer encompassed by a clad insulating layer. The semiconductor device may contain an etched hole for guiding light to and from the core insulating layer from a transmitter or to a receiver. | 10-22-2009 |
| 20090042327 | Method for assembling array-type semiconductor laser device - According to an aspect of the present invention, there is provided a method for assembling a semiconductor laser device, including: preparing a laser chip including: a substrate; stripe waveguides that are formed on the substrate and that each includes a gain producing area and a window area; electrodes formed on the stripe waveguides; an insulating layer formed on the electrodes; a metal layer formed on the insulating layer; projections arranged at an interval in the window areas; and joining structures connected to the electrodes and formed in the window areas; preparing a submount including: a first solder; second solders arranged at the interval; and submount electrodes connected to the second solders; contacting the laser chip to the submount by fitting the projections with respect to the second solders; and heating the submount and the laser chip. | 02-12-2009 |
| 20110171767 | MANUFACTURING METHOD FOR A THIN FILM TRANSISTOR-LIQUID CRYSTAL DISPLAY - A pixel unit of TFT-LCD array substrate and a manufacturing method thereof is disclosed. In the manufacturing method, besides a first insulating layer and a passivation layer, a second insulating layer is adopted to cover the gate island, and forms an opening on the gate island to expose the channel region, the source region and the drain region of the TFT. A gray tone mask and a photoresist lifting-off process are utilized to perform patterning, so that the TFT-LCD array substrate can be achieved with just three masks. | 07-14-2011 |
| 20100279447 | DBR LASER WITH IMPROVED THERMAL TUNING EFFICIENCY - A distributed Bragg reflector (DBR) includes a base substrate and a gain medium formed on the base substrate. A waveguide positioned above the base substrate in optical communication with the gain medium and defines a gap extending between the base substrate and the waveguide along a substantial portion of the length thereof. The waveguide having a grating formed therein. A heating element is in thermal contact with the waveguide and electrically coupled to a controller electrically configured to adjust optical properties of the waveguide by controlling power supplied to the heating element. | 11-04-2010 |
| 20080286893 | Light emitting device having protrusion and recess structure and method of manufacturing the same - The semiconductor light emitting device having a protrusion and recess structure includes: a lower clad layer disposed on a substrate; an active layer formed on one portion of a top surface of the lower clad layer; an upper clad layer formed on the active layer; a first electrode formed on the upper clad layer; and a second electrode that is formed on a protrusion and recess structural pattern region formed on a portion of the top surface of the lower clad layer not occupied by the active layer. | 11-20-2008 |
| 20080286892 | METHOD FOR FABRICATING THREE-DIMENSIONAL PHOTONIC CRYSTAL - A method for fabricating a three-dimensional photonic crystal comprises the steps of: forming a dielectric thin film; injecting ions selectively into the dielectric thin film by using a focus ion beam to form a mask on the dielectric thin film; forming a pattern by selectively removing an exposed part of the dielectric thin film at which the mask is not formed on the dielectric thin film; forming a sacrificial layer on the dielectric thin film having the pattern formed therein; and flattening the sacrificial layer formed on the dielectric thin film until the pattern comes to the surface. | 11-20-2008 |
| 20080293176 | METHOD FOR MANUFACTURING SEMICONDUCTOR OPTICAL DEVICE - A method for manufacturing a semiconductor optical device includes: forming a first resist pattern on top surface of a laminated semiconductor structure; forming channels and a waveguide ridge by dry etching using the first resist pattern as a mask; forming an SiO | 11-27-2008 |
| 20080305567 | NITRIDE-BASED LIGHT EMITTING DEVICE AND MANUFACTURING METHOD THEREOF - A light emitting device according to an exemplary embodiment of the present invention includes: an n-type cladding layer; a p-type cladding layer; an active layer interposed between the n-type cladding layer and the p-type cladding layer; and an ohmic contact layer contacting the p-type cladding layer or the n-type cladding layer and comprising a first film that comprises a transparent conductive zinc oxide having a one-dimensional nano structure, wherein the one-dimensional nano structure is at least one selected from a nano-column, a nano rod, and a nano wire. | 12-11-2008 |
| 20100273281 | LASER DIODE AND METHOD FOR FABRICATING SAME - A laser diode and method for fabricating same, wherein the laser diode generally comprises an InGaN compliance layer on a GaN n-type contact layer and an AlGaN/GaN n-type strained super lattice (SLS) on the compliance layer. An n-type GaN separate confinement heterostructure (SCH) is on said n-type SLS and an InGaN multiple quantum well (MQW) active region is on the n-type SCH. A GaN p-type SCH on the MQW active region, an AlGaN/GaN p-type SLS is on the p-type SCH, and a p-type GaN contact layer is on the p-type SLS. The compliance layer has an In percentage that reduces strain between the n-type contact layer and the n-type SLS compared to a laser diode without the compliance layer. Accordingly, the n-type SLS can be grown with an increased Al percentage to increase the index of refraction. This along with other features allows for reduced threshold current and voltage operation. | 10-28-2010 |
| 20090191657 | ALL-SILICON RAMAN AMPLIFIERS AND LASERS BASED ON MICRO RING RESONATORS - Methods of manufacturing a lasing device are provided by some embodiments, the methods including: creating a silicon micro ring with a predetermined radius and a predetermined first cross-sectional dimension; creating a silicon waveguide with a predetermined second cross-sectional dimension, the silicon waveguide spaced from the silicon micro ring by a predetermined distance; and wherein the predetermined distance, the predetermined radius, the predetermined first cross-sectional dimension, and the predetermined second cross-sectional dimension are determined so that at least one first whispering gallery mode resonant frequency of the silicon micro ring and at least one second whispering gallery mode resonant frequency of the silicon micro ring are separated by an optical phonon frequency of silicon. | 07-30-2009 |
| 20090004765 | Method of manufacturing micro-optic device - A micro-optic device including a complicate structure and a movable mirror is made to be manufactured in a reduced length of time. A silicon substrate and a single crystal silicon device layer with an intermediate layer of silicon dioxide interposed therebetween defines a substrate on which a layer of mask material is formed and is patterned to form a mask having the same pattern as the configuration of the intended optical device as viewed in plan view. A surface which is to be constricted as a mirror surface is chosen to be in a plane of the silicon crystal. Using the mask, the device layer is vertically etched by a reactive ion dry etching until the intermediate layer is exposed. Subsequently, using KOH solution, a wet etching which is anisotropic to the crystallographic orientation is performed with an etching rate which is on the order of 0.1 μm/min for a time interval on the order of ten minutes is performed to convert the sidewall surface of the mirror into a smooth crystallographic surface. Subsequently, the intermediate layer is selectively subject to a wet etching to remove the intermediate layer only in an area located below the movable part of the optical device. | 01-01-2009 |
| 20090117678 | Semiconductor laser with a weakly coupled grating - A semiconductor laser with a semiconductor substrate, a laser layer arranged on the semiconductor substrate, a waveguide arranged parallel to the laser layer and a strip shaped grating structure is disclosed. The laser layer, the waveguide and the grating are arranged in a configuration which results in weak coupling between the laser light and the grating structure, so that the laser light interacts with an increased number of grating elements. A process for the production of such a semiconductor laser is also disclosed. | 05-07-2009 |
| 20100197056 | Method for producing nitride semiconductor laser light source and apparatus for producing nitride semiconductor laser light source - A method for producing a nitride semiconductor laser light source is provided. The nitride semiconductor laser light source has a nitride semiconductor laser chip, a stem for mounting the laser chip thereon, and a cap for covering the laser chip. The laser chip is encapsulated in a sealed container composed of the stem and the cap. The method for producing this nitride semiconductor laser light source has a cleaning step of cleaning the surface of the laser chip, the stem, or the cap. In the cleaning step, the laser chip, the stem, or the cap is exposed with ozone or an excited oxygen atom, or baked by heat. The method also has, after the cleaning step, a capping step of encapsulating the laser chip in the sealed container composed of the stem and the cap. During the capping step, the cleaned surface of the laser chip, the stem, or the cap is kept clean. This method provides a long-life nitride semiconductor laser light source the light emission intensity of which is not easily reduced after a long period of use. | 08-05-2010 |
| 20090111200 | Method for Fabricating Electronic and Photonic Devices on a Semiconductor Substrate - A method for fabricating photonic and electronic devices on a substrate is disclosed. Multiple slabs are initially patterned and etched on a layer of a substrate. An electronic device is fabricated on a first one of the slabs and a photonic device is fabricated on a second one of the slabs, such that the electronic device and the photonic device are formed on the same layer of the substrate. | 04-30-2009 |
| 20100317134 | Nitride semiconductor laser device and method of producing the same - A method of producing a nitride semiconductor laser device includes: forming a wafer including a nitride semiconductor layer of a first conductivity type, an active layer of a nitride semiconductor, a nitride semiconductor layer of a second conductivity type, and an electrode pad for the second conductivity type stacked in this order on a main surface of a conductive substrate and also including stripe-like waveguide structures parallel to the active layer; cutting the wafer to obtain a first type and a second type of laser device chips; and distinguishing between the first type and the second type of chips by automatic image recognition. The first type and the second type of chips are different from each other in position of the stripe-like waveguide structure with respect to a width direction of each chip and also in area ratio of the electrode pad to the main surface of the substrate. | 12-16-2010 |
| 20110076791 | METHOD FOR MANUFACTURING GaN-BASED FILM LED - A method for manufacturing GaN-based film LED based on masklessly transferring photonic crystal structure is disclosed. Two dimensional photonic crystals are formed on a sapphire substrate. Lattice quality of GaN-based epitaxy on the sapphire substrate is improved, and the internal quantum efficiency of GaN-based LED epitaxy is increased. After the GaN-based film is transferred onto heat sink substrate, the two dimensional photonic crystals structure is masklessly transferred onto the light exiting surface of the GaN-based film by using different etching rates between the GaN material and the SiO2 mask, so that light extraction efficiency of the GaN-based LED is improved. That is, the GaN-based film LED according to the invention has a relatively high illumination efficiency and heat sink. | 03-31-2011 |
| 20100311195 | DBR Laser with Improved Thermal Tuning Efficiency - A distributed Bragg reflector (DBR) includes a base substrate and a gain medium formed on the base substrate. A waveguide positioned above the base substrate in optical communication with the gain medium and defines a gap extending between the base substrate and the waveguide along a substantial portion of the length thereof. The waveguide may have a grating formed therein. A heating element is in thermal contact with the waveguide and electrically coupled to a controller configured to adjust optical properties of the waveguide by controlling power supplied to the heating element. | 12-09-2010 |
| 20100297795 | Method for producing semiconductor optical device - A method for producing a semiconductor optical device, includes the steps of: forming a semiconductor region including a semiconductor layer on a substrate; preparing a mold including a pattern surface, the pattern surface including an arrangement of patterns each including first to n-th pattern portions; forming a first mask on the semiconductor region with the mold by a nano-imprint technique; forming first to n-th periodic structures in each of the device sections in the semiconductor region by using the first mask, the first to n-th periodic structures respectively corresponding to the first to n-th pattern portions; forming a second mask after the first mask is removed, the second mask including a first pattern on an i-th periodic structure (1≦i≦n) among the first to n-th periodic structures in a first section of the device sections and including a second pattern on a j-th periodic structure (1≦j≦n) among the first to n-th periodic structures in a second section of the device sections; and forming first and second stripe mesas in the first and second sections respectively by using the second mask. | 11-25-2010 |
| 20090023237 | INTEGRATED OPTICAL ISOLATOR - There is provided an integrated optical isolator has a structure obtained by integrating a semiconductor laser and an optical isolator, simple manufacturing steps, efficiently absorbs a backward propagation light of the optical isolator, and prevents a stray light from being generated. In an integrated optical isolator in which a semiconductor waveguide layer is layered on a compound semiconductor substrate, a semiconductor laser is formed on a one-side part of the semiconductor waveguide layer, and an optical isolator is formed on an other-side part, a laser current injection electrode is arranged on an upper portion of an active layer of a certain semiconductor waveguide layer in the semiconductor laser, terminal absorbing layers are arranged at the backward propagation light output waveguide output end of the optical isolator on both sides of the semiconductor laser. | 01-22-2009 |
| 20100105158 | METHOD OF FABRICATING SEMICONDUCTOR DEVICE - A method of fabricating a semiconductor device having high output power and excellent long-term reliability by preventing thermal adverse influence exerted at the time of window structure formation is provided. The method comprises a 1st step of forming predetermined semiconductor layers | 04-29-2010 |
| 20090111201 | Ridge and mesa optical waveguides - Apparatus including: a substrate layer having a substantially planar top surface; an optically conductive peak located and elongated on, and spanning a first thickness measured in a direction generally away from, the top surface; the optically conductive peak having first and second lateral walls each including distal and proximal lateral wall portions, the proximal lateral wall portions intersecting the top surface; and first and second sidewall layers located on the distal lateral wall portions, the sidewall layers not intersecting the top surface and spanning a second thickness that is less than the first thickness measured in the same direction. | 04-30-2009 |
| 20110027926 | Optical semiconductor device having diffraction grating disposed on both sides of waveguide and its manufacture method - An active layer ( | 02-03-2011 |
| 20110027925 | SURFACE EMITTING LASER, METHOD FOR PRODUCING SURFACE EMITTING LASER, AND IMAGE FORMING APPARATUS - A surface emitting laser includes a lower multilayer mirror, an active layer, and an upper multilayer mirror stacked onto a substrate. A first current confinement layer having a first electrically conductive region and a first insulating region is formed above or below the active layer using a first trench structure. A second current confinement layer having a second electrically conductive region and a second insulating region is formed above or below the first current confinement layer using a second trench structure. The first and second trench structures extend from a top surface of the upper multilayer mirror towards the substrate such that the second trench structure surrounds the first trench structure. When the surface emitting laser is viewed in an in-plane direction of the substrate, a boundary between the first electrically conductive region and the first insulating region is disposed inside the second electrically conductive region. | 02-03-2011 |
| 20110086453 | LIGHT EMITTING DEVICE HAVING ISOLATING INSULATIVE LAYER FOR ISOLATING LIGHT EMITTING CELLS FROM EACH OTHER AND METHOD OF FABRICATING THE SAME - Disclosed is a light emitting device having an isolating insulative layer for isolating light emitting cells from one another and a method of fabricating the same. The light emitting device comprises a substrate and a plurality of light emitting cells formed on the substrate. Each of the light emitting cells includes a lower semiconductor layer, an upper semiconductor layer positioned on one region of the lower semiconductor layer, and an active layer interposed between the lower and upper semiconductor layers. Furthermore, an isolating insulative layer is filled in regions between the plurality of light emitting cells to isolate the light emitting cells from one another. Further, wirings electrically connect the light emitting cells with one another. Each of the wirings connects the lower semiconductor layer of one light emitting cell and the upper semiconductor layer of another light emitting cell adjacent to the one light emitting cell. | 04-14-2011 |
| 20100330720 | GROUP-III NITRIDE BASED LASER DIODE AND METHOD FOR FABRICATING SAME - A laser diode comprising a first separate confinement heterostructure and an active region on the first separate confinement heterostructure. A second separate confinement heterostructure is on the active region and one or more epitaxial layers is on the second separate confinement heterostructure. A ridge is formed in the epitaxial layers with a first mesa around the ridge. The first mesa is 0.1 to 0.2 microns above the second confinement heterostructure. | 12-30-2010 |
| 20110136276 | NITRIDE SEMICONDUCTOR LIGHT-EMITTING DEVICE AND METHOD FOR FABRICATION THEREOF - A nitride semiconductor laser device uses a substrate with low defect density, contains reduced strains inside a nitride semiconductor film, and thus offers a satisfactorily long useful life. On a GaN substrate ( | 06-09-2011 |
| 20120309121 | METHOD OF MAKING SEMICONDUCTOR OPTICAL INTEGRATED DEVICE - A method of making a semiconductor optical integrated device includes the steps of forming, on a substrate, a plurality of semiconductor integrated devices including a first optical semiconductor element having a first bonding pad and a second optical semiconductor element; forming a plurality of bar-shaped semiconductor optical integrated device arrays by cutting the substrate, each of the semiconductor optical integrated device arrays including two or more semiconductor optical integrated devices; alternately arranging the plurality of semiconductor optical integrated device arrays and a plurality of spacers in a thickness direction of the substrate so as to be fixed in place; and forming a coating film on a facet of the semiconductor optical integrated device array. Furthermore, the spacer has a movable portion facing the first bonding pad, the movable portion protruding toward the first bonding pad and being displaceable in a protruding direction. | 12-06-2012 |
| 20100279446 | OPTICAL PHASE CONJUGATION LASER DIODE - A phase-conjugating resonator that includes a semiconductor laser diode apparatus that comprises a phase-conjugating array of retro-reflecting hexagon apertured hexahedral shaped corner-cube prisms, an electrically and/or optically pumped gain-region, a distributed bragg reflecting mirror-stack, a gaussian mode providing hemispherical shaped laser-emission-output metalized mirror. Wherein, optical phase conjugation is used to neutralize the phase perturbating contribution of spontaneous-emission, acoustic phonons, quantum-noise, gain-saturation, diffraction, and other intracavity aberrations and distortions that typically destabilize any stimulated-emission made to undergo amplifying oscillation within the inventions phase-conjugating resonator. Resulting in stablized high-power laser-emission-output into a single low-order fundamental transverse cavity mode and reversal of intra-cavity chirp that provides for high-speed internal modulation capable of transmitting data at around 20-Gigabits/ps. | 11-04-2010 |
| 20090317928 | HIGH TEMPERATURE STABLE FIBER GRATING SENSOR AND METHOD FOR PRODUCING SAME - A method of producing a thermally stable grating allows the grating to be placed in environments where temperatures reach 1000° C. and where the grating is relatively stable and has very low loss from scatter. These gratings have spectral characteristics that allow them to be concatenated so as to form a sensor array. The method requires a step of lowering the characteristic intensity threshold of a waveguide by at least 25%, followed by irradiating the waveguide with femtosecond pulses of light having a sufficient intensity and for a sufficient duration to write the grating so that at least 60% of the grating remains after exposures of at least 10 hours at a temperature of at least 1000° C. Pre-writing a Type I grating before writing a minimal damage Type II grating lowers the characteristic threshold of the waveguide so that a stable low damage type II grating can be written; alternatively providing a hydrogen or deuterium loaded waveguide before writing the grating lowers the characteristic threshold of the waveguide. | 12-24-2009 |
| 20120003767 | OPTICAL MODULATOR AND METHOD FOR MANUFACTURING SAME - An optical modulator according to the present invention is configured at least by a semiconductor layer subjected to a doping process so as to exhibit a first conductivity type, and a semiconductor layer subjected to a doping process so as to exhibit a second conductivity type. Further, in the optical modulator, at least the first conductivity type semiconductor layer, a dielectric layer, the second conductivity type semiconductor layer, and a transparent electrode optically transparent in at least a near-infrared wavelength region are laminated in order. | 01-05-2012 |
| 20090068778 | Buried Heterostructure Device Having Integrated Waveguide Grating Fabricated By Single Step MOCVD - The device is an optoelectronic device or transparent waveguide device that comprises a growth surface, a growth mask, an optical waveguide core mesa and a cladding layer. The growth mask is located on the semiconductor surface and defines an elongate growth window having a periodic grating profile. The optical waveguide core mesa is located in the growth window and has a trapezoidal cross-sectional shape. The cladding layer covers the optical waveguide core mesa and extends over at least part of the growth mask. Such devices are fabricated by providing a wafer comprising a growth surface, growing an optical waveguide core mesa on the growth surface by micro-selective area growth at a first growth temperature and covering the optical waveguide core mesa with cladding material at a second growth temperature, lower than the first growth temperature. | 03-12-2009 |
| 20120058581 | METHOD OF MANUFACTURING LASER DIODE - Manufacturing a laser diode includes growing an active layer, a first InP layer, and a diffraction grating layer; forming an alignment mark having a recess by etching the diffraction grating layer and the first InP layer; forming a first etching mask; forming a diffraction grating in the diffraction grating layer using the first etching mask; forming a modified layer containing InAsP on a surface of the alignment mark recess by supplying a first source gas containing As and a second source gas containing P; growing a second InP layer on the diffraction grating layer and on the alignment mark; forming a second etching mask on the second InP layer; selectively etching the second InP layer embedded in the recess of the alignment mark through the second etching mask by using the modified layer serving as an etching stopper; and forming a waveguide structure using the alignment mark. | 03-08-2012 |
| 20110104839 | SEMICONDUCTOR LASER DEVICE AND METHOD OF MANUFACTURING THE SAME - A semiconductor laser device includes a substrate and a semiconductor layer formed on a surface of the substrate and having a waveguide extending in a first direction parallel to the surface, wherein the waveguide is formed on a region approaching a first side from a center of the semiconductor laser device in a second direction parallel to the surface and intersecting with the first direction, a first region separated from the waveguide on a side opposite to the first side of the waveguide and extending parallel to the first direction and a first recess portion separated from the waveguide on an extension of a facet of the waveguide, intersecting with the first region and extending in the second direction are formed on an upper surface of the semiconductor laser device, and a thickness of the semiconductor layer on the first region is smaller than a thickness of the semiconductor layer on a region other than the first region. | 05-05-2011 |
| 20110183452 | SEMICONDUCTOR LIGHT EMITTING DEVICE, ITS MANUFACTURING METHOD, SEMICONDUCTOR DEVICE AND ITS MANUFACTURING METHOD - A method of manufacturing a semiconductor light emitting device made of nitride III-V compound semiconductors is includes an active layer made of a first nitride III-V compound semiconductor containing In and Ga, such as InGaN; an intermediate layer made of a second nitride III-V compound semiconductor containing In and Ga and different from the first nitride III-V compound semiconductor, such as InGaN; and a cap layer made of a third nitride III-V compound semiconductor containing Al and Ga, such as p-type AlGaN, which are deposited in sequential contact. | 07-28-2011 |
| 20120315716 | TAPER-ETCHING METHOD AND METHOD OF MANUFACTURING NEAR-FIELD LIGHT GENERATOR - A method of taper-etching a layer to be etched that is made of SiO | 12-13-2012 |
| 20120077294 | SURFACE EMITTING PHOTONIC DEVICE - A surface emitting photonic device including a substrate; and a waveguide structure on the substrate. The waveguide structure includes an active region along its longitudinal axis and the active region is for generating light. The waveguide structure also has a trench formed therein transverse to the active region and defining a first wall forming an angled facet at one end of the active region, the first wall having a normal that is at a non-parallel angle relative to the longitudinal axis of the waveguide structure. The trench also defines a second wall located opposite the first wall. | 03-29-2012 |
| 20100291717 | OPTIMIZED PROCESS FOR FABRICATING LIGHT-EMITTING DEVICES USING ARTIFICIAL MATERIALS - The present invention relates to a process for fabricating light-emitting devices. More particularly, the aim of the invention is to allow the fabrication of light emitters with improved efficiency by using artificial materials, enabling antireflection or high-reflectivity treatments to be carried out. | 11-18-2010 |
| 20120083058 | Optical semiconductor device and method for manufacturing the same - There is provided an optical semiconductor device having a first optical semiconductor element including an InP substrate, a lower cladding layer formed on the InP substrate, a lower optical guide layer which is formed on the lower cladding layer and is composed of AlGaInAs, an active layer which is formed on the lower optical guide layer and has a multiple quantum well structure where a well layer and a barrier layer that is formed of AlGaInAs are alternately stacked, an upper optical guide layer which is formed on the active layer and is composed of InGaAsP, and an upper cladding layer formed on the upper optical guide layer. | 04-05-2012 |
| 20100297796 | METHOD FOR MANUFACTURING SEMICONDUCTOR DEVICE - A method for manufacturing a semiconductor device including growing an InAlGaAsP layer having a thickness of 1.0 μm or more on a surface of an InP semiconductor layer at a growth temperature of 680 degrees C. or more, a composition ratio “X” of Ga in InAlGa of the InAlGaAsP being 0≦X≦0.08. | 11-25-2010 |
| 20080311694 | METHOD FOR MANUFACTURING SEMICONDUCTOR OPTICAL DEVICE | 12-18-2008 |
| 20080299691 | GaN lasers on ALN substrates and methods of fabrication - Ga(In)N-based laser structures and related methods of fabrication are proposed where Ga(In)N-based semiconductor laser structures are formed on AlN or GaN substrates in a manner that addresses the need to avoid undue tensile strain in the semiconductor structure. In accordance with one embodiment of the present invention, a Ga(In)N-based semiconductor laser is provided on an AlN or GaN substrate provided with an AlGaN lattice adjustment layer where the substrate, the lattice adjustment layer, the lower cladding region, the active waveguiding region, the upper cladding region, and the N and P type contact regions of the laser form a compositional continuum in the semiconductor laser. Additional embodiments are disclosed and claimed. | 12-04-2008 |
| 20120270347 | METHOD OF MANUFACTURING RIDGE-TYPE SEMICONDUCTOR LASER - A method of manufacturing a ridge-type semiconductor laser includes the steps of forming a stacked semiconductor layer including an active layer and an etch stop layer on first and second surfaces of a substrate, etching the stacked semiconductor layer on the second surface, forming a semiconductor portion on the second surface, forming a ridge waveguide portion by etching the stacked semiconductor layer on the first surface to a first depth, forming semiconductor diffraction grating portions by etching the semiconductor portion to a second depth, and forming a diffraction grating section by providing resin diffraction grating portions between the semiconductor diffraction grating portions. The etching of the stacked semiconductor layer on the first surface and the etching of the semiconductor portion are performed simultaneously by using first and second mask portions. | 10-25-2012 |
| 20120100650 | VICINAL SEMIPOLAR III-NITRIDE SUBSTRATES TO COMPENSATE TILT OF RELAXED HETERO-EPITAXIAL LAYERS - A method for fabricating a semi-polar III-nitride substrate for semi-polar III-nitride device layers, comprising providing a vicinal surface of the III-nitride substrate, so that growth of relaxed heteroepitaxial III-nitride device layers on the vicinal surface compensates for epilayer tilt of the III-nitride device layers caused by one or more misfit dislocations at one or more heterointerfaces between the device layers. | 04-26-2012 |
| 20110159620 | METHOD TO FORM SEMICONDUCTOR LASER DIODE - The process of the present invention to form a mask made of inorganic material containing silicon reduces the plasma damage induced in the semiconductor layers due to the plasma-ashing. The semiconductor material is heat-treated at a high temperature after the growth thereof to form an oxide layer positively in the surface of the semiconductor material before it is covered by the silicon inorganic film. This inorganic film is dry-etched by an etchant containing fluorine to get a mask for forming a mesa and for growing burying layer selectively. | 06-30-2011 |
| 20130023077 | METHOD FOR MANUFACTURING SEMICONDUCTOR OPTICAL DEVICE AND SEMICONDUCTOR OPTICAL DEVICE - A method for manufacturing a semiconductor optical device includes the steps of growing a stacked semiconductor layer on a substrate having a cleavage direction in a first direction; forming a first mask having a plurality of openings arranged in the first direction; forming a mark array by etching the stacked semiconductor layer using the first mask; forming a second mask having first and second openings extending in a second direction intersecting the first direction; forming first and second grooves, and a waveguide mesa by etching the stacked semiconductor layer using the second mask; and producing a laser diode bar by cleaving a substrate product including the waveguide mesa. First and second residual marks are formed on the upper surface of the waveguide mesa. First and second transfer marks are formed on the bottoms of the first and the second grooves, respectively. | 01-24-2013 |
| 20080233668 | METHOD FOR MANUFACTURING SEMICONDUCTOR OPTICAL DEVICE - A method for manufacturing a semiconductor optical device includes: forming a laminated semiconductor structure of GaN-based materials on a semiconductor wafer, the laminated semiconductor structure forming a laser diode of GaN-based materials, including an active layer having a quantum well structure; cleaving the semiconductor wafer including the laminated semiconductor structure to expose a cleaved end face of the laminated semiconductor structure; and forming an SiO | 09-25-2008 |
| 20130137202 | TEMPERATURE CONTROL DEVICE FOR OPTOELECTRONIC DEVICES - Current may be passed through an n-doped semiconductor region, a recessed metal semiconductor alloy portion, and a p-doped semiconductor region so that the diffusion of majority charge carriers in the doped semiconductor regions transfers heat from or into the semiconductor waveguide through Peltier-Seebeck effect. Further, a temperature control device may be configured to include a metal semiconductor alloy region located in proximity to an optoelectronic device, a first semiconductor region having a p-type doping, and a second semiconductor region having an n-type doping. The temperature of the optoelectronic device may thus be controlled to stabilize the performance of the optoelectronic device. | 05-30-2013 |
