Class / Patent application number | Description | Number of patent applications / Date published |
385131000 | Multilayer structure (mixture) | 67 |
20080205842 | Photonic structure - A photonic structure has rods arranged with periodicity which is of a non-translational symmetry and defined in a polar coordinate system, which uses a distance in a radial direction and an angle in a circumferential direction, and has a center of the polar coordinate system used as a reference. A heterointerface is provided between adjoining areas of the plurality of areas. The positions of the centers of the polar coordinate systems of the plurality of areas are different. Lines of rods are smoothly connected between adjoining areas of the plurality of areas at the heterointerfaces. Rods are removed in a spiral shape or in a curve whose radius of curvature changes, to form an optical waveguide in the spiral shape or in the curve. | 08-28-2008 |
20080232755 | PHOTONIC CRYSTALS BASED ON NANOSTRUCTURES - The present invention provides for photonic crystals comprising nanostructures grown on a conducting or insulating substrate, and a method of making the same. The photonic crystals can be used in components such as artificial photonic crystals for photonic devices and circuits. | 09-25-2008 |
20080232756 | MULTIPLE-CORE PLANAR OPTICAL WAVEGUIDES AND METHODS OF FABRICATION AND USE THEREOF - A multiple-core optical waveguide comprises: a substrate; lower and upper waveguide core layers; a waveguide core between the upper and lower waveguide core layers; upper and lower cladding; and middle cladding between the upper and lower waveguide core layers substantially surrounding the waveguide core. Each of the lower, middle, and upper claddings has a refractive index less than refractive indices of the lower waveguide core layer, the upper waveguide core layer, and the waveguide core. Along at least a given portion of the optical waveguide, the upper and lower waveguide core layers extend bilaterally substantially beyond the lateral extent of a propagating optical mode supported by the optical waveguide, the lateral extent of the supported optical mode being determined at least in part by the width of the waveguide core along the given portion of the optical waveguide. | 09-25-2008 |
20080253727 | Optical Waveguide - An optical waveguide and method of making are disclosed. The method of making includes forming a layer on a substrate of a substantially optically transparent material. The layer includes an inner area and an outer area. A sufficient number of voids can be created in the inner area to form a first index of refraction. A plurality of the voids have a dimension that is less than a wavelength of the light beam. A sufficient number of voids can be created in the outer area to form a second index of refraction less than the first index. | 10-16-2008 |
20080298760 | Thermally Stabilized Waveguides - An apparatus comprising a planar optical waveguide having an optical core and optical cladding next to the optical core. The optical core or cladding includes a plurality of particles therein. Each particle has a nucleus and polymeric molecules permanently bonded to the nucleus to form a shell. A plurality of nuclei are dispersed in said core or cladding. | 12-04-2008 |
20080298761 | LOW LOSS, HIGH AND LOW INDEX CONTRAST WAVEGUIDES IN SEMICONDUCTORS - A system in one general embodiment includes a waveguide structure comprising a core of an alloy of Group III-V materials surrounded by an oxide (which may include one or more Group III-V metals), wherein an interface of the oxide and core is characterized by oxidation of the alloy for defining the core. A method in one general approach includes oxidizing a waveguide structure comprising an alloy of Group III-V materials for forming a core of the alloy surrounded by an oxide. | 12-04-2008 |
20090010605 | MULTILAYER OPTIC DEVICE AND SYSTEM AND METHOD FOR MAKING SAME - An optic device, system and method for making are described. The optic device includes a first solid phase layer having a first index of refraction with a first photon transmission property and a second solid phase layer having a second index of refraction with a second photon transmission property. The first and second layers are conformal to each other. The optic device may be fabricated by vapor depositing a first layer and then vapor depositing a second layer thereupon. The first layer may be deposited onto a blank or substrate. The blank or substrate may be rotated during deposition. Further, a computer-controlled shutter may be used to alter the deposition rate of material along an axis of the optic device. Alternatively, the optic device may be moved at varying speeds through a vapor stream to alter the deposition rate of material. | 01-08-2009 |
20090052856 | Flexible Film Optical Waveguide Using Organic-Inorganic Hybrid Material and Fabrication Method Thereof - Disclosed herein is a flexible film optical waveguide, which is in flexible film form and includes upper and lower cladding layers, each of which is formed of an organic-inorganic hybrid material, and a core layer provided between the upper and lower cladding layers and formed of an organic-inorganic hybrid material having a refractive index higher than that of the organic-inorganic hybrid material of each of the upper and lower cladding layers. In addition, a method of fabricating such a flexible film optical waveguide is also provided. | 02-26-2009 |
20090067797 | OPTICAL WAVEGUIDE RADIATION CONTROL - An integrated optical planar waveguide chip comprising materials and structures such as substrates, adhesives, capping materials, and waveguide structures which are absorbing at the wavelength of the working radiation. | 03-12-2009 |
20090067798 | Optical waveguide film and manufacturing method thereof - An optical waveguide film includes a film including a clad layer and a core layer covered by the clad layer; and an adhesive layer formed at least on one surface of the film, having a rough structured surface having an arithmetic mean surface roughness of 0.1 to 2.0 μm, and having a storage modulus at 25° C. of 10 to 100 MPa obtained by dynamic viscoelastic measurement in torsion mode with a frequency of 1 Hz. | 03-12-2009 |
20090067799 | Optical Device and Optical Device Manufacturing Method - Scattering loss at a reflecting or transmitting end face of an optical unit is reduced, and the end face is easily manufactured at low cost. An optical waveguide cable ( | 03-12-2009 |
20090087155 | PLANAR LIGHTWAVE CIRCUIT, MANUFACTURING METHOD THEREOF, AND LIGHT WAVEGUIDE DEVICE - To provide a PLC and the like, which can improve the optical coupling efficiency by coupling an optical element to a light waveguide part without having a gap. The PLC includes a light waveguide part and an optical element mount part. The light waveguide part has a lower clad layer, a core layer, and an upper clad layer formed on a part of a silicon substrate as a substrate. The optical element mount part has an LD, which is to be optically coupled at the light waveguide end face as an end face of the light waveguide, loaded on the silicon substrate. At the light waveguide end face, an end face of the lower clad layer is recessed with respect to an end face of the core layer and an end face of the upper clad layer towards a direction away from the LD. | 04-02-2009 |
20090087156 | OPTICAL DEVICE WITH CHANNEL WAVEGUIDE STRUCTURE AND METHOD OF FABRICATING - The present invention prefers to an optical device with a channel waveguide structure as well as a method of fabrication. A thin waveguide layer ( | 04-02-2009 |
20090092368 | METHOD FOR FABRICATING THREE-DIMENSIONAL PHOTONIC CRYSTAL - At least one exemplary embodiment is directed to a method for fabricating a three-dimensional photonic crystal. In the method for fabricating the three-dimensional photonic crystal, a plurality of layers can be defined as one unit, and the total thickness of the one unit can be controlled such that an average layer-thickness of the plurality of layers in the one unit is about equal to the ideal layer-thickness so that a photonic band-gap occurs in a desired wavelength region. | 04-09-2009 |
20090097811 | Photonic Crystal and Method of Fabrication - A method is disclosed for forming a photonic crystal in a homogeneous layer of material. The method enables the fabrication of 1D, 2D, or 3D photonic crystals. Photonic crystals in accordance with embodiments of the present invention exhibit low temperature sensitivity and low device curvature. In some embodiments, photonic crystals in accordance with embodiments of the present invention are integrated with mechanical elements, such as micromechanical, nanomechanical, microelectronic, and microfluidics devices and systems. | 04-16-2009 |
20090103875 | OPTICAL WAVEGUIDE AND METHOD FOR MANUFACTURING THE SAME - An optical waveguide includes: a center layer including at least two core layers whose edges are on substantially the same plane, and a first cladding layer provided between adjacent core layers; and a second cladding layer provided at least on both of front and rear surfaces of the center layer. At least surfaces of the core layer and the first cladding layer that are in contact with the second cladding layer include at least one resin selected from the group consisting of a resin having a hydroxyl group and a resin containing a silicon-silicon bond at a main chain thereof, and the second cladding layer includes a silicone resin. | 04-23-2009 |
20090116804 | Integrated Device For Heat Assisted Magnetic Recording - An apparatus includes a first waveguide configured to focus an electromagnetic wave to a focal region, and a second waveguide to further condense the light to an optical spot. The second waveguide includes a metallic structure defining an opening having one end positioned adjacent to the focal region and a multilayer structure positioned in the opening, the multilayer structure including a first layer of dielectric material, and second and third layers of dielectric material positioned on opposite sides of the first layer. A layer of lower index of refraction than that of the first dielectric layer may be positioned adjacent to the inner walls of the opening in the second waveguide to efficiently excite surface plasmons, and propagate them with low loss. | 05-07-2009 |
20090116805 | Scalable semiconductor waveguide amplifier - One embodiment of the present method and apparatus encompasses an apparatus that may have: a predetermined length, the self-imaging semiconductor waveguide having first and second opposed sides; quantum wells disposed within the self-imaging semiconductor waveguide along the length of the self-imaging semiconductor waveguide, the quantum wells being formed of a quantum well gain material; microchannel cooler that extends substantially the width of the self-imaging semiconductor waveguide, the microchannel cooler located adjacent the first side of the self-imaging semiconductor waveguide; and a plurality of pump arrays arranged along the microchannel cooler opposed from the first side of the self-imaging semiconductor waveguide; wherein the quantum well gain material is photopumped through the microchannel cooler. | 05-07-2009 |
20090136191 | MAGNETIC MATERIAL FOR MAGNETO-OPTICAL ISOLATOR - A magneto-optical structure is provided. The magneto-optical structure includes a substrate. A waveguide layer is formed on the substrate for guiding electromagnetic radiation received by the magneto-optical structure. The waveguide layer includes magnetic oxide material that comprises ABO | 05-28-2009 |
20090136192 | OPTICAL WAVEGUIDE DEVICE FOR TOUCH PANEL AND MANUFACTURING METHOD THEREOF - A touch panel optical waveguide device which obviates the need for an alignment operation for alignment between light emitting cores of an optical waveguide thereof and light emitting means and alignment between light receiving cores of the optical waveguide thereof and light receiving means, and to provide a production method for the optical waveguide device. A recess ( | 05-28-2009 |
20090142026 | Optical Waveguide Film And Photoelectric Film - An optical waveguide film and an electrical and optical hybrid circuit film having a high durability for folding while keeping the core size of the optical waveguide at a desired level are provided. The optical waveguide film is flexible, having a core made of a resin that composes an optical waveguide, a clad made of a resin, and a hollow groove extending in the same direction in which the core extends wherein at least at a portion of the optical waveguide film is folded so that the folding axis intersects with the core-extending direction at the portion. The films can contribute to the miniaturization of electronic devices. | 06-04-2009 |
20090148114 | THREE-DIMENSIONAL PHOTONIC CRYSTAL AND MANUFACTURING METHOD THEREOF - A three-dimensional photonic crystal includes a structure that includes first, second, third, and fourth layers in this order. The structure of each layer includes a flat surface as one end surface, and first, second, and third structural portions. The first structural portion has a first width along the flat surface and a first height from the flat surface. The second structural portion has a second width larger than the first width and a second height larger than the first height. The third structural portion has a width and a height that continuously or stepwise change in the extending direction of the structure. The flat surface at the structural portion of one of two adjacent layers in the first layer to the fourth layer contacts a surface opposite to the flat surface at the second structural portion of the other of the two adjacent layers. | 06-11-2009 |
20100021120 | APPARATUS FOR THE COLLECTION AND TRANSMISSION OF ELECTROMAGNETIC RADIATION - A collector for propagating incident radiation is disclosed. The collector may comprise a light directing component coupled to a buffer component, a first propagation component coupled to the buffer component and configured to transmit the incident radiation into a collector region through one of a plurality of windows, and an optical transport assembly coupled to an end of the collector region and having a second propagation component. Each light directing component may be configured to redirect the incident radiation from a first direction to a second direction, and the collector region may include a plurality of regions exhibiting a refractive index value that gradually transitions from about 1.5 to about 2.0. The second propagation component may be further configured to retain the incident radiation. | 01-28-2010 |
20100040337 | OPTICAL WAVEGUIDE WITH POSITION RECOGNITION MARK AND METHOD FOR PRODUCING THE SAME - An optical waveguide includes: a core portion through which light propagates, a cladding portion enclosing the core portion along a direction of light propagation, and a colored resin for position recognition marking, the optical waveguide having substantially planar outer surfaces including principal surfaces thereof, and the colored resin being embedded in the optical waveguide at a position that does not substantially overlap the core portion when viewed from a direction perpendicular to a principal surface of the optical waveguide and does not substantially contact the core portion. | 02-18-2010 |
20100061689 | Process for Fabricating Buried Optical Waveguides Using Laser Ablation - The present invention is concerned with a process for fabricating a buried optical waveguide, comprising providing a multi-layer piece of material having a waveguide core layer, generating a laser beam and producing by ablation at least two trenches by applying the laser beam onto the multi-layer piece of material. The two trenches extend through the multi-layer piece of material including the core layer. Upon the ablation, melted material from the multi-layer piece is produced and the core layer is encapsulated between the two trenches with the melted material to produce the buried optical waveguide in the multi-layer piece of material. The present invention also relates to a buried optical waveguide comprising a multi-layer piece of material having a waveguide core layer, at least two trenches laser ablated through the multi-layer piece of material including the core layer and encapsulating material having melted from the multi-layer piece upon laser ablation and leaked to cover and therefore encapsulate the core layer in the at least two trenches to thereby form the buried optical waveguide. | 03-11-2010 |
20100067861 | LIGHT GUIDE AND LIGHT GUIDE STRUCTURE - An optical waveguide structure has excellent heat resistance and a low water absorbing property and can be manufactured with a low material cost. Such an optical waveguide structure includes: an optical waveguide having two surfaces, a core layer including core portions and cladding portions each having a refractive index lower than that of each of the core portions, the core layer having two surfaces, and cladding layers provided so as to make contact with the two surfaces of the core layer and having a refractive index lower than that of each of the core portions; and conductor layers provided on the two surfaces of the optical waveguide. In the optical waveguide structure, each of the cladding layers is formed of a norbornene-based polymer as a major component thereof. Further, it is preferred that the norbornene-based polymer is composed of molecules each represented by the following formula 1 as a major component thereof: | 03-18-2010 |
20100092144 | MULTIPLE-CORE PLANAR OPTICAL WAVEGUIDES AND METHODS OF FABRICATION AND USE THEREOF - A multiple-core optical waveguide comprises: a substrate; lower and upper waveguide core layers; a waveguide core between the upper and lower waveguide core layers; upper and lower cladding; and middle cladding between the upper and lower waveguide core layers substantially surrounding the waveguide core. Each of the lower, middle, and upper claddings has a refractive index less than refractive indices of the lower waveguide core layer, the upper waveguide core layer, and the waveguide core. Along at least a given portion of the optical waveguide, the upper and lower waveguide core layers extend bilaterally substantially beyond the lateral extent of a propagating optical mode supported by the optical waveguide, the lateral extent of the supported optical mode being determined at least in part by the width of the waveguide core along the given portion of the optical waveguide. | 04-15-2010 |
20100142904 | OPTICAL WAVEGUIDE, OPTICAL WAVEGUIDE MOUNTING SUBSTRATE, AND LIGHT TRANSMITTING AND RECEIVING DEVICE - An optical waveguide is provided. The optical waveguide includes: a layered structure including: a first cladding layer; a second cladding layer; and a core layer that is sandwiched between the first cladding layer and the second cladding layer, wherein an inclined surface is formed on at least one longitudinal end of the layered structure; and an outer cladding layer that seals at least a portion of the inclined surface corresponding to the core layer, wherein a refractive index of the outer cladding layer is smaller than that of the core layer. | 06-10-2010 |
20100150513 | LIGHT EXTRACTION FILM WITH NANOPARTICLE COATINGS - A multifunctional optical film for enhancing light extraction includes a flexible substrate, a structured layer having nanoparticles of different sizes, and a backfill layer. The structured layer effectively uses microreplicated diffractive or scattering nanostructures located near enough to the light generation region to enable extraction of an evanescent wave from an organic light emitting diode (OLED) device. The backfill layer has a material having an index of refraction different from the index of refraction of the structured layer. The backfill layer also provides a planarizing layer over the structured layer in order to conform the light extraction film to a layer of an OLED display device. The film may have additional layers added to or incorporated within it to an emissive surface in order to effect additional functionalities beyond improvement of light extraction efficiency. | 06-17-2010 |
20100178018 | Photonic Via Waveguide for Pixel Arrays - Photonic passive structure to couple and guide light between photonic active devices ( | 07-15-2010 |
20100178019 | DISPLAY DEVICE UNIFORMING LIGHT DISTRIBUTION THROUGHOUT AREAS AND METHOD FOR MANUFACTURING SAME - Disclosed are an optical display device producing uniform light distribution and a method of fabricating such devices. The optical display device has waveguides arranged in vertical and horizontal directions. The waveguide has a conical shape whose cross-section decreases towards the light-projection side thereof. At least one of the size, height, spacing, and refraction index of the waveguide is designed to be different for each section, depending on an incident angle and/or intensity of light inputted from a light source. Therefore, the intensity of projected light can be made uniform over all sections of the optical device. | 07-15-2010 |
20100260462 | Method for Making Optical Waveguides - A method for making a waveguide comprises (a) providing a waveguide structure comprising a substrate ( | 10-14-2010 |
20110026892 | OPTICAL FIBER STRUCTURE WITH FILTERING THIN FILM - An optical fiber with filtering thin film includes a first ferrule having a first through hole and a first contact surface. A first fiber is disposed into the first through hole, extending to the first contact surface. A first interface coupling material is between the first ferrule and the first fiber. A second ferrule has a second through hole and a second contact surface. A second fiber is disposed into the second through hole, extending to the second contact surface. A second interface coupling material is between the second ferrule and the second fiber. The first contact surface and the second contact surface are parallel and have an included tilt angle from a perpendicular transverse plane of first fiber. An optical filtering film is disposed between the first contact surface and the second contact surface. The first fiber and the second fiber are aligned. | 02-03-2011 |
20110038588 | OPTICAL COUPLER - Provided is an optical coupler. The optical coupler includes a lower cladding layer on a substrate, a core layer on the lower cladding layer, the core layer comprising a diffraction grating coupler and an optical waveguide, and an upper cladding layer on the core layer. The upper cladding layer has a thickness of about one quarter of a wavelength of an optical signal passing through the core layer divided by a refractive index of the first upper cladding layer. Thus, Fresnel reflection may be minimized, and also, it may prevent a Fabry-Perot interferometer from occurring. | 02-17-2011 |
20110085773 | OPTICAL WAVEGUIDE AND METHOD OF FORMING THE SAME - Provided is an optical waveguide and a method of forming the same. The optical waveguide comprises inductive thin films and a waveguide thin film. The inductive thin films are disposed to be separated from each other. The waveguide thin film fills a gap which separates the inductive thin films, and covers at least one portion of the inductive thin films. A refractive index of the waveguide thin film is greater than refractive indexes of the inductive thin films. | 04-14-2011 |
20110135266 | DEVICE AND METHOD FOR TRANSMITTING LIGHT SIGNALS - A device for transmitting light signals includes two electrode plates, a spacing structure, a cladding fluid, and a core fluid. The spacing structure, the cladding and core fluids are disposed between the electrode plates. The refractive index of the core fluid is higher than that of the cladding fluid. The core fluid is located on an electrode of one of the electrode plates, and its shape corresponds to the shape of that electrode. The shape and position is changeable and programmable by the electrodes of one of the electrode plates. The core fluid is further surrounded by the cladding fluid, forming an optical waveguide. Via these arrangements, the interface between the core and cladding fluids is much smoother than that between a fluid and a solid, so that the light signals are less likely to scatter while transmitted, in the core fluid. Therefore, the attenuation and reduction of the intensity of the light signals can be decreased. A method for transmitting light signals is also provided. | 06-09-2011 |
20110188828 | OPTICAL INPUT/OUTPUT DEVICE FOR PHOTO-ELECTRIC INTEGRATED CIRCUIT DEVICE AND METHOD OF FABRICATING SAME - A photo-electric integrated circuit device comprises an on-die optical input/output device. The on-die optical input/output device comprises a substrate having a trench, a lower cladding layer disposed in the trench and having an upper surface lower than an upper surface of the substrate, and a core disposed on the lower cladding layer at a distance from sidewalls of the trench and having an upper surface at substantially the same level as the upper surface of the substrate. | 08-04-2011 |
20110200293 | LIGHT EXTRACTION FILM WITH NANOPARTICLE COATINGS - A multifunctional optical film for enhancing light extraction includes a flexible substrate, a structured layer having nanoparticles of different sizes, and a backfill layer. The structured layer effectively uses microreplicated diffractive or scattering nanostructures located near enough to the light generation region to enable extraction of an evanescent wave from an organic light emitting diode (OLED) device. The backfill layer has a material having an index of refraction different from the index of refraction of the structured layer. The backfill layer also provides a planarizing layer over the structured layer in order to conform the light extraction film to a layer of an OLED display device. The film may have additional layers added to or incorporated within it to an emissive surface in order to effect additional functionalities beyond improvement of light extraction efficiency. | 08-18-2011 |
20110243520 | OPTICAL WAVEGUIDE STRUCTURE AND METHOD OF MANUFACTURE THEREOF - An optical waveguide structure including a III-V semiconductor substrate, a III-V semiconductor top layer, and an etch stop layer sandwiched therebetween, the etch stop layer containing aluminium and phosphorous, the top layer including first and second spaced apart recesses extending through the top layer to the etch stop layer and defining an optical waveguide therebetween. Also a method of manufacture of an optical waveguide structure including the steps of: providing a multilayer semiconductor wafer including a III-V semiconductor substrate, a III-V semiconductor top layer and an etch stop layer sandwiched therebetween, the etch stop layer including aluminium and phosphorous; and etching through the top layer to the etch stop layer by use of a dry etch containing chlorine to provide two spaced apart recesses defining the optical waveguide therebetween. | 10-06-2011 |
20110262093 | OLED LIGHT EXTRACTION FILMS HAVING INTERNAL NANOSTRUCTURES AND EXTERNAL MICROSTRUCTURES - A light extraction film having internal nanostructures and external microstructures for organic light emitting diode (OLED) devices. The light extraction film includes a flexible substantially transparent film, a low index nanostructured layer applied to the film, and a high index planarizing backfill layer applied over the nanostructured layer. External optical microstructures are applied to the flexible substantially transparent film on a side opposite the nanostructured layer to enhance light extraction from the OLED devices while providing for a more uniform luminance distribution. | 10-27-2011 |
20110280533 | ULTRA-LOW LOSS HOLLOW CORE WAVEGUIDE USING HIGH-CONTRAST GRATINGS - Optical waveguides using segmented periodically-spaced high contrast gratings bounding a hollow core propagation region on at least two sides. Incident light is received in a hollow waveguide (HW) region (core) between opposing HCG faces which provide lateral confinement in response to glancing reflections of the incident light beam from high refractive index segments of the HCG as it traverses the core. Embodiments are described for planar waveguides (1D) having a planar core between two planar HCGs, as well as | 11-17-2011 |
20120134638 | WAVEGUIDE SYSTEM AND METHODS - Waveguide apparatuses and methods are provided. A waveguide method ( | 05-31-2012 |
20120155824 | ELECTRO-OPTICAL ELEMENT - An electro-optical element includes a core layer made of an electro-optical material, a clad structure disposed on each of opposite sides of the core layer and configured to form an optical waveguide together with the core layer, and a pair of electrode layers, one of which being disposed on one side of the clad structure and another being disposed on another side of the clad structure. The clad structure includes a first clad layer and a second layer. The second clad layer has a dielectric permittivity larger than that of the first clad layer, and the second clad layer has a thickness thicker than that of the first clad layer. | 06-21-2012 |
20120224820 | SPOT-SIZE CONVERTER - A spot-size converter includes a cladding layer having a principal surface; a first core layer disposed on the principal surface and having a light input/output portion and a first transition portion having a width W | 09-06-2012 |
20120281957 | PLASMONIC AND PHOTONIC RESONATOR STRUCTURES AND METHODS FOR LARGE ELECTROMAGNETIC FIELD ENHANCEMENTS - Devices for producing localized surface plasmon resonances are described having a plasmonic resonator and a photonic structure electromagnetically coupled to the plasmonic resonator. The device can include a hybrid photonic plasmonic resonator that contains plasmonic and photonic resonators, and are optionally coupled to a photonic waveguide, or a plasmonic resonator coupled directly to a photonic waveguide. The plasmonic resonator can be one or more nanoparticles. The devices can produce substantial increases in coupling efficiencies and sensitivity for use in several applications, including SERS and refractive index sensing. | 11-08-2012 |
20130051748 | PLASMONIC WAVEGUIDES, CIRCUITS, AND SYSTEMS - Waveguide structure for propagating a surface plasmon polariton, including an inter-metal plasmonic waveguide ( | 02-28-2013 |
20130071083 | OPTICAL WAVEGUIDE - An optical waveguide includes: a substrate; a first dielectric layer positioned on the substrate; a graphene layer including graphene formed on the first dielectric layer along the lengthwise direction of the substrate and for transmitting incident light through the graphene; and a second dielectric layer positioned on the first dielectric layer and the graphene layer. | 03-21-2013 |
20130315547 | OPTICAL WAVEGUIDE HAVING A VARYING INDEX GRADIENT - A photoacoustic detection device including a nanophotonic circuit including a first chip on which is formed at least one optical waveguide and in which is formed a set of cavities defining a Helmholtz resonator; at least one optical source capable of emitting an optical signal in a given wavelength range, capable of being modulated at an acoustic modulation frequency, this source being attached to the first chip; a second chip forming a cap for said cavities and including acoustic sensors; and electronic circuits for processing the output of the acoustic sensors formed in the first or the second chip. Further, an optical waveguide comprising, on a silicon substrate, a silicon germanium core with a variable germanium concentration along a direction perpendicular to the substrate, said core being covered with a cladding silicon layer. | 11-28-2013 |
20130343715 | Single Crystals with Internal Doping with Laser Ions Prepared by a Hydrothermal Method - Single heterogeneous crystals are described that contain multiple regimes, adjacent regimes varying from one another with regard to function. Also disclosed is a hydrothermal epitaxial growth process that can be utilized to form the single heterogeneous crystals. The single heterogeneous crystals can exhibit enhanced performance when used as a laser gain medium as compared to previously known single crystals and multi-crystal constructs. The heterogeneous single crystal can be utilized for thin disk lasers and can minimize the thermal distortion effects at high powers. The heterogeneous crystal can also serve as an embedded waveguide. | 12-26-2013 |
20140010509 | OPTICAL DEVICE USING A PLASMONIC WAVEGUIDE, AND OPTICAL ISOLATOR - An optical device having a plasmonic waveguide, in which the plasmonic waveguide has a layered structure of at least three layers that a ferromagnetic metal layer, a first dielectric layer, and a second dielectric layer are layered in this order, in which the first and second dielectric layers are layers that allow light to be transmitted therethrough, and in which a refractive index of the second dielectric layer is higher than a refractive index of the first dielectric layer; and an optical isolator, having the optical device. | 01-09-2014 |
20140105556 | SURFACE WAVEGUIDE HAVING A TAPERED REGION AND METHOD OF FORMING - A method for forming a waveguide having a thin-core region, a thick-core region, and a transition region of tapered thickness between them is disclosed. The method comprises forming a lower core layer of a first material on a lower cladding, forming a thin central core layer of a second material on the first core layer, forming an upper core layer of the first material on the central core layer, and etching the upper core layer in an etchant such that it is removed from the thin-core region and its thickness monotonically changes from its as-deposited thickness to extinction across the transition region, where the central core layer protects the lower core layer from exposure to the etchant. | 04-17-2014 |
20140212104 | ATHERMAL WAVEGUIDE AND METHOD OF MANUFACTURING THE SAME - Provided are an athermal waveguide and a method of manufacturing the same. The athermal waveguide includes: a substrate having a protruded region; a first material layer formed on the protruded region to counteract thermal expansion; and a second material layer formed on the first material layer a position corresponding to the protruded region and formed of a same base material as the protruded region. | 07-31-2014 |
20140254998 | SEMICONDUCTOR OPTICAL WAVEGUIDE DEVICE AND METHOD FOR MANUFACTURING THE SAME - A semiconductor optical waveguide device includes a substrate having a first area and a second area, and first, second, and semiconductor mesas on the substrate. The first semiconductor mesa includes a cladding layer and a first mesa portion on the second area, the first mesa portion including first and second portions. The second semiconductor mesa includes an intermediate layer, a first core layer, and first and second mesa portions on the first and second area, respectively. The third semiconductor mesa includes a second core layer, and first and second mesa portions having a greater width than that of the second semiconductor mesa. The first portion of the first semiconductor mesa has a substantially the same width as the second mesa portion of the second semiconductor mesa. The first core layer is optically coupled to the second core layer through the intermediate layer disposed between the first and second core layers. | 09-11-2014 |
20140270672 | OPTICAL WAVEGUIDE BODY - An optical waveguide body includes a first layer of optically transmissive material and a second layer of optically transmissive material in contact with the first layer. At least one of the first and second layers is tapered and the first layer has a first index of refraction and the second layer has a second index of refraction less than the first index of refraction and the first and second indices of refraction are both greater than about 1.0. | 09-18-2014 |
20140286616 | Layer Having a Non-linear Taper and Method of Fabrication - A method for forming a non-linear thickness-profile in a first layer of a first material is disclosed. The method comprises forming an accelerator layer of a second material on the first layer and forming a mask layer disposed on the accelerator layer, wherein the mask layer enables the accelerator layer to expose the first layer to a first etchant in a first region, where the exposure time for each point along a first axis varies non-linearly as a function of distance from a first point on the first axis. Since the time for which the first layer is exposed to the first etch in the first region is non-linear, the thickness of the first layer in the first region changes non-linearly along the first axis. | 09-25-2014 |
20150030298 | PHOTONIC VIA WAVEGUIDE FOR PIXEL ARRAYS - Light guiding structures are provided to improve the light coupling between photonic active devices and the top of a metallization layer stack interconnecting these photonic active devices. Each light guiding structure comprises a hole extending between the near surface of the photonic active devices and the top surface of the metallization layer stack, said hole being filled with dielectrics or a combination of dielectrics and metals. Such a light guiding structure removes from the optical path of light rays, the interfaces between the metallization layers, thereby confining light laterally and enabling interconnects with increased thickness and more levels of metal. This results in the suppression of multiple reflections and optical crosstalk. The light guiding structures can have cross-section diagonals with sub-wavelength dimensions can be fabricated after all CMOS process steps, thus having minimal interference and maximal compatibility with CMOS processing. | 01-29-2015 |
20150050001 | COPLANAR WAVEGUIDE - A coplanar waveguide electronic device is formed on a substrate. The waveguide includes a signal ribbon and a ground plane. The signal ribbon is formed of two or more signal lines of a same level of metallization that are electrically connected together. The ground plane is formed of an electrically conducting material which includes rows of holes. | 02-19-2015 |
20150086169 | COMPOSITIONS, OPTICAL COMPONENT, SYSTEM INCLUDING AN OPTICAL COMPONENT, DEVICES, AND OTHER PRODUCTS - The present inventions relate to optical components which include quantum confined semiconductor nanoparticles, wherein at least a portion of the nanoparticles include a ligand attached to a surface thereof, the ligand being represented by the formula: X-Sp-Z, wherein: X represents a primary amine group, a secondary amine group, a urea, a thiourea, an imidizole group, an amide group, an other nitrogen containing group, a carboxylic acid group, a phosphonic or arsonic acid group, a phosphinic or arsinic acid group, a phosphate or arsenate group, a phosphine or arsine oxide group; Sp represents a spacer group, such as a group capable of allowing a transfer of charge or an insulating group; and Z represents: (i) a reactive group capable of communicating specific chemical properties to the nanocrystal as well as provide specific chemical reactivity to the surface of the nanocrystal, and/or (ii) a group that is cyclic, halogenated, or polar a-protic. Compositions, systems, kits, films, inks, and TFEL lamps are also disclosed. | 03-26-2015 |
20150331188 | OPTICAL WAVEGUIDE DRY FILM, AND OPTICAL WAVEGUIDE MANUFACTURING METHOD AND OPTICAL WAVEGUIDE USING OPTICAL WAVEGUIDE DRY FILM - The present invention relates to a dry film for an optical waveguide which has a carrier base material, a resin layer for an optical waveguide that can be cured by active energy ray or heat, and a protective film. The surface of the protective film that is in contact with the resin layer for an optical waveguide is a roughened surface. | 11-19-2015 |
20160004010 | DIRECT WRITABLE AND ERASABLE WAVEGUIDES IN OPTOELECTRONIC SYSTEMS - Technologies are generally described to form a waveguide in a polymer multilayer comprising a first and second polymer layer. The waveguide may be formed by directing light beams toward the polymer multilayer to form first and second cladding regions in the polymer multilayer, where the first and second cladding regions comprise a mixture of the first and second polymer layers. The first and second cladding regions may define a third cladding region and a waveguide core therebetween, where the third cladding region comprises a portion of the second polymer layer, and the waveguide core comprises a portion of the first polymer layer. In some examples, the polymer multilayer may be formed on a substrate such that the waveguide is formed on the substrate. Additionally, the waveguide may be formed temporarily to test components of an optoelectronic system and then erased by heating the polymer multilayer to destroy the waveguide core, or the waveguide may be formed as a default optical interconnection configuration that may be changed to alter the functional mode of the backplane in the manner of a jumper setting. | 01-07-2016 |
20160011368 | SYSTEM FOR STABILIZING THE TEMPERATURE SENSITIVITY IN PHOTONIC CIRCUITS COMPRISING THERMOELASTIC OPTICAL CIRCUIT CLADDINGS | 01-14-2016 |
20160025927 | FABRICATION OF LOW-LOSS, LIGHT-WAVEGUIDING, ORIENTATION-PATTERNED SEMICONDUCTOR STRUCTURES - Methods for the fabrication of orientation-patterned semiconductor structures are provided. The structures are light-waveguiding structures for nonlinear frequency conversion. The structures are periodically poled semiconductor heterostructures comprising a series of material domains disposed in a periodically alternating arrangement along the optical propagation axis of the waveguide. The methods of fabricating the orientation-patterned structures utilize a series of surface planarization steps at intermediate stages of the heterostucture growth process to provide interlayer interfaces having extremely low roughnesses. | 01-28-2016 |
20160070060 | METHOD FOR THE FORMATION OF NANO-SCALE ON-CHIP OPTICAL WAVEGUIDE STRUCTURES - A strip of sacrificial semiconductor material is formed on top of a non-sacrificial semiconductor material substrate layer. A conformal layer of the non-sacrificial semiconductor material is epitaxially grown to cover the substrate layer and the strip of sacrificial semiconductor material. An etch is performed to selectively remove the strip of sacrificial semiconductor material and leave a hollow channel surrounded by the conformal layer and the substrate layer. Using an anneal, the conformal layer and the substrate layer are reflowed to produce an optical waveguide structure including the hollow channel. | 03-10-2016 |
20160252655 | OPTICAL WAVEGUIDE PHOTOSENSITIVE RESIN COMPOSITION, PHOTOCURABLE FILM FOR FORMING OPTICAL WAVEGUIDE CORE LAYER, OPTICAL WAVEGUIDE USING SAME, AND MIXED FLEXIBLE PRINTED CIRCUIT BOARD FOR OPTICAL/ELECTRICAL TRANSMISSION | 09-01-2016 |
20160252675 | OPTICAL WAVEGUIDE, OPTICAL WAVEGUIDE MANUFACTURING METHOD, AND OPTICAL MODULE | 09-01-2016 |
20170235047 | WAVEGUIDE | 08-17-2017 |
20220137295 | THERMALLY COMPENSATED SLOT WAVEGUIDE - A photonic integrated circuit includes a slot optical waveguide having an optical core with sub-wavelength slot therein that is partially filled with a first lower-index material having a negative thermo-optic coefficient. The slot may also include a second lower-index material having a positive thermo-optic coefficient. The relative volume of the first lower-index material within the slot may be configured to provide athermal or nearly-athermal operation. Example applications include integrated AWG MUX/DEMUX devices, Mach-Zehnder modulators, and micro-ring resonators or modulators implemented with silicon-based or silicon-nitride based slot waveguides with reduced sensitivity to temperature changes. | 05-05-2022 |