Abstract: Disclosed herein is a light emitting diode (LED) package. The present invention is directed to a light emitting diode (LED) package capable of efficiently dissipating heat generated from LEDs. The present invention is also directed to a LED package in which a plurality of LEDs are disposed and heat generated from the plurality of LEDs is efficiently dissipated.

Abstract: In an aspect, an organic light-emitting display apparatus and a method of manufacturing the same are provided. The organic light-emitting display apparatus may include a substrate; a display unit formed on the substrate; and a thin film encapsulating layer encapsulating the display unit. The thin film encapsulating layer may include a plurality of organic layers and inorganic layers that are laminated alternately. At least one of the plurality of the inorganic films may include a first layer formed of a first material, a second layer formed of a second material other than the first material, and an intermediate layer provided between the first and second layers.

Abstract: A light emitting module includes a circuit board having a plurality of reflective portions arranged in one direction and connection portions connecting the plurality of reflective portions, light emitting devices mounted on the plurality of reflective portions, and lens units disposed to cover the light emitting devices within boundaries of surfaces, of the plurality of reflective portions, on which the light emitting devices are mounted. A width of each of the connection portions in the other direction, perpendicular to the one direction thereof, is smaller than a diameter of each of the lens units, thus reducing a generation of a dark portion.

Abstract: The present application relates to a quantum dot lens and a manufacturing method thereof, wherein the quantum dot comprises a lens body in the form of a rotator, a light incident surface and a light exit surface are formed on the lens body, the centers of the light incident surface and the light exit surface are located in the center axis of the lens body; and quantum dot materials are filled inside the lens body. The quantum dot lens can be used with a single LED. Since the light excited from the quantum dot materials can directly meet the need of increasing the light emitting angle, the quantum dot lens has no need to be used with a second lens for light distribution; the quality of the backlight used in the backlight illumination can be improved; and the high gamut in the direct type backlight can be achieved.

Abstract: A light source may comprise a housing, a window mounted in a front plane of the housing, a window length spanning a front plane length, and a linear array of light-emitting elements within the housing. The linear array may be aligned with and emit light through the window, and the linear array may span the window length, wherein first and last light-emitting elements of the linear array are positioned adjacent to widthwise edges of the window, and wherein window sidewalls at the widthwise edges are aligned flush with housing sidewalls.

Abstract: Pkg resin crack is suppressed after dicing. A light emitting device 1 where a light emitting device 2 that emits light is mounted on a lead frame 3 and that uses a resin cavity molding package 5 having an integrally molded lead frames 3, 4 constituting electrodes that correspond to the light emitting element 2 and resin, wherein roundness is given to a part or all of a cutting plane corner part of a retention section (hanger lead 3a, 4a) that become a cause of crack generation due to the retention sections (hanger leads 3a, 4a) of the lead frames giving stress concentration to resin at the time of cutting by a blade 7.

Abstract: A light-emitting diode (LED) lighting device includes a substrate, a first bottom electrode, a bottom transparent isolation layer, a first vertical LED, a second vertical LED, a first top transparent electrode, and a second top transparent electrode. The substrate has a first recess therein. The first bottom electrode is disposed in the first recess and is reflective. The first vertical LED and the second vertical LED are disposed in the first recess and on the first bottom electrode. The first bottom transparent isolation layer is disposed in the first recess. The first top transparent electrode is electrically connected to the first vertical LED. The second top transparent electrode is electrically connected to the second vertical LED. The first top transparent electrode, the second top transparent electrode, and the first bottom electrode cooperate to electrically connect the first vertical LED and the second vertical LED in series.

Abstract: The present invention provides a metallized via-holed ceramic substrate having (1) a sintered ceramic substrate, (2) an electroconductive via formed in the sintered ceramic substrate, having an electroconductive metal closely filled in a through-hole of the sintered ceramic substrate, wherein the electroconductive metal contains a metal (A) with melting point of 600° C. to 1100° C., a metal (B) with higher melting point than the metal (A), and an active metal, (3) a wiring pattern on at least one face of the sintered ceramics substrate, having an electroconductive surface layer and a plating layer thereon, wherein the electroconductive surface layer consists of an electroconductive metal containing the metal (A), the metal (B), and an active metal, (4) an active layer formed in the interface between the electroconductive via and the sintered ceramic substrate, and (5) an active layer formed in the interface between the electroconductive surface layer and the sintered ceramic substrate.

Abstract: The disclosure relates to lattice-mismatched core-shell quantum dots (QDs). In certain embodiments, the lattice-mismatched core-shell QDs are used in methods for photovoltaic or photoconduction applications. They are also useful for multicolor molecular, cellular, and in vivo imaging.

Abstract: Light emitting assemblies comprise a plurality of Light Emitting Diode (LED) dies arranged and attached to common substrate to form an LED array having a desired optimum packing density. The LED dies are wired to one another and are attached to landing pads on the substrate for receiving power from an external electrical source via an interconnect device. The assembly comprises a lens structure, wherein each LED die comprises an optical lens disposed thereover that is configured to promote optimal light transmission. Each optical lens has a diameter that is between about 1.5 to 3 times the size of a respective LED die, and is shaped in the form of a hemisphere. Fillet segments are integral with and interposed between the adjacent optical lenses, and provide sufficient space between adjacent optical lenses so that the diameters of adjacent optical lenses do not intersect with one another.

Abstract: A light-emitting unit is provided including a mounting substrate and a semiconductor light-emitting device. The mounting substrate includes a first pad, a second pad, and one or more third pads provided between the first pad and the second pad. The semiconductor light-emitting device includes a plurality of light-emitting elements having a first light-emitting element and a second light-emitting element separated in a first direction. Each light-emitting element includes a first external terminal and a second external terminal separated in the first direction. A first external terminal of the first light-emitting element is bonded to the first pad. A second external terminal of the first light-emitting element and a first external terminal of the second light-emitting element are each bonded to one of the one or more third pads. A second external terminal of the second light-emitting element is bonded to the second pad.

Abstract: An electroluminescent display or lighting product incorporates a panel including a collection of distinct light-emitting elements formed on a substrate. A plurality of distinct local seals are formed over respective individual light-emitting elements or groups of light-emitting elements. Each local seal is formed by depositing a low melting temperature glass powder suspension or paste using inkjet technology, and fusing the glass powder using a scanning laser beam having a tailored beam profile. The local seal may be used in conjunction with a continuous thin film encapsulation structure. Optical functions can be provided by each local seal, including refraction, filtering, color shifting, and scattering.

Abstract: An epoxy resin composition according to an embodiment of the present invention comprises an epoxy resin, 0.05-190 parts by weight, based on 10 parts by weight of the epoxy resin, of a polyester-based curing agent, wherein the epoxy resin comprises a triazine derivative epoxy compound and a siloxane compound containing an alicyclic epoxy group and a siloxane group.

Abstract: A lens (12; 32; 42; 52) comprising a transparent main body (13; 43; 53), wherein a surface (14, 15; 14, 45; 54, 55) of the main body (13; 43; 53) is at least partly covered with an internally reflecting reflection layer (17), the lens (12; 32; 42; 52) has at least one first focal point (F1) and at least one second focal point (F2), at least the first focal point (F1) lies at least partly on a non-covered surface region of the main body (15; 45; 55), and at least one phosphor element (18) bears against the main body (13; 43; 53) at a contact region (19) having at least one first focal point (F1).

Abstract: The present invention relates to a method for assembling a circuit carrier with a housing component and furthermore to an optical unit for emitting and/or receiving radiation that is fabricated using this particular method of assembling and aligning the circuit carrier with the housing component. The method comprises the following steps: providing said circuit carrier, wherein on said circuit carrier there is arranged at least one electronic component, and providing said housing component having at least one first opening; aligning said circuit carrier in a way that said electronic component is aligned with respect to said first opening in the housing component, wherein the electronic component is directly used as a fiducial for its own position on the circuit carrier; fixing the circuit carrier at the housing component.

Abstract: A fluorescent composite resin substrate white light LED includes a fluorescent composite resin substrate, two conductive brackets, a light emitting unit, two conductive lines and a package material. The fluorescent composite resin substrate is formed from a mixture through a curing reaction. Each of the conductive brackets is partially connected to the substrate. The light emitting unit is disposed on the substrate. The conductive lines are connected to the light emitting unit and respectively connected to the conductive brackets. The package material is formed from a mixture through a curing reaction. By fixing the light emitting unit at the fluorescent composite resin substrate, when applied to white light LED operations, the present invention achieves effects of emitting light through six planes, having high light flux and good heat dissipation, and significantly increasing production yield rate and speed without incurring different color temperatures at front and reverse sides.

Abstract: A light-emitting device capable of ensuring an electric connection between a light-emitting element and an electrode without generating any problem in practical use, by both connecting methods with a solder and a connector, and a lighting device provided with the light-emitting device are provided. The light-emitting device according to the present invention has a plurality of LED chips, and a soldering electrode land and a connector connecting electrode land electrically connected to the chips, on a ceramic substrate. The soldering electrode land is formed of a first conductive material having a function to prevent diffusion to a solder, and the connector connecting electrode land is formed of a second conductive material having a function to prevent oxidation.

Abstract: Light emitting devices and methods of integrating micro LED devices into light emitting device are described. In an embodiment a light emitting device includes a reflective bank structure within a bank layer, and a conductive line atop the bank layer and elevated above the reflective bank structure. A micro LED device is within the reflective bank structure and a passivation layer is over the bank layer and laterally around the micro LED device within the reflective bank structure. A portion of the micro LED device and a conductive line atop the bank layer protrude above a top surface of the passivation layer.

Abstract: A semiconductor light emitting device includes a substrate having first and second electrode patterns on at least one surface thereof, a light emitting structure on a surface of the substrate, a first electrode structure, a second electrode structure, an insulating layer, a first connection portion connecting the first electrode structure and the first electrode pattern, and a second connection portion connecting the second electrode structure extending outwardly from the light emitting structure and the second electrode pattern.

Abstract: A composition is capable of curing via condensation reaction. The composition uses a new condensation reaction catalyst. The new condensation reaction catalyst is used to replace conventional tin catalysts. The composition can react to form a gum, gel, rubber, or resin.

Abstract: A light-emitting diode package structure including a chip carrier portion, a light-emitting diode chip, and a package material is provided. The light-emitting diode chip is disposed on the chip carrier portion of the package. The package material is filled in the chip carrier portion and covers the light-emitting diode chip. The package material includes a matrix material, a plurality of first powder particles, and a plurality of second powder particles. The first powder particles and the second powder particles are distributed in the matrix material. Each first powder particle is a wavelength conversion material. Each second powder particle has a shell-like structure.

Abstract: A lead frame for mounting LED elements includes a frame body region and a large number of package regions arranged in multiple rows and columns in the frame body region. The package regions each include a die pad on which an LED element is to be mounted and a lead section adjacent to the die pad, the package regions being further constructed to be interconnected via a dicing region. The die pad in one package region and the lead section in another package region upward or downward adjacent to the package region of interest are connected to each other by an inclined reinforcement piece positioned in the dicing region.

Abstract: A light-emitting diode module includes: at least one first light-emitting diode chip which is based on the material system AlInGaN and which emits a first radiation in the blue spectral range, at least one second light-emitting diode chip which is based on the material system InGaAlP and which emits a second radiation in the red spectral range, and a conversion element, which is disposed downstream of at least the first light-emitting diode chip and is designed for converting part of the first radiation into a third radiation in the green to green-yellow spectral range, wherein the conversion element comprises a first phosphor and a second phosphor, the first phosphor emits at a shorter wavelength than the second phosphor, the first phosphor has an absorption that decreases toward relatively long wavelengths in the long-wave blue spectral range, and the second phosphor has an absorption maximum in the middle blue spectral range.

Abstract: The light emitting device is provided with a substrate, semiconductor light emitting elements mounted on the substrate, a mold frame that surrounds the periphery of the light emitting elements on the substrate, and resin layers that fill the inside of the mold frame. The mold frame includes a first mold frame, and a second mold frame formed on top of the first mold frame. The resin layers include a first resin layer that embeds the light emitting elements in resin and is formed with a height approximately equal to the height of the top of the first mold frame, and a second resin layer on top of the first resin layer that is formed with a height approximately equal to the height of the top of the second mold frame. At least one of the resin layers (which are the first resin layer and the second resin layer) includes wavelength-shifting material to change the wavelength of light emitted from the semiconductor light emitting elements.

Abstract: A light-emitting device includes a substrate including a mirror surface region on its upper surface, a semiconductor light-emitting element disposed in the mirror surface region, and an encapsulating layer joined onto the upper surface of the substrate. The encapsulating layer includes a lower layer that is in contact with the upper surface of the substrate, covers the surrounding of the semiconductor light-emitting element, and contains phosphor; and an upper layer that is positioned on the lower layer, and has a larger phosphor content per unit area than that of the lower layer.

Abstract: Provided is a light emitting device with improved light extracting efficiency and further higher heat releasing performance. A light emitting device includes a planar lead frame having a first lead and a second lead, and includes a light emitting element mounted on the first lead, a resin frame surrounding a periphery of the light emitting element, a first sealing resin filled in the inner side of the resin frame and sealing the light emitting element, and a second sealing resin covering the resin frame and the first sealing resin. Lower end of inner surface of the resin frame is arranged only on the first lead, and at an outside of the resin frame, and the second resin member covers at least a part of the first lead and the second lead. Of the back-surface of the first lead, a region directly under the blight emitting element is exposed.

Abstract: A material composition with specific segment wavelength matching refractive index includes (a) resin or a composite thereof to serve as a bonding agent and (b) a medium material of metal oxides or complex metal oxides of specific particle size to serve as an additive for specific segment wavelength matching refractive index. The composition is formed by combining the bonding agent and additive. The composition material uses the wavelength of light emitting from a light-emitting diode (LED) die or excited from a fluorescent agent as the range of a segment to add nanometer particles of D=?/4n optic thickness as basis for formation of an effective medium layer and thus providing a matching refractive index for wavelength of the specific segment bandwidth. Corresponding to different refractive indexes nx of LED die materials, proper amounts of nanometer particles are selectively added to have the refractive index match the LED die.

Abstract: A semiconductor package includes a semiconductor die having a plurality of terminals, a molding compound encapsulating the semiconductor die, and a pluggable lead dimensioned for insertion into an external receptacle. The pluggable lead protrudes from the molding compound and provides a separate electrical pathway for more than one terminal of the semiconductor die. The separate electrical pathways of the pluggable lead can be provided by electrical conductors isolated from one another by electrical insulator such as molding compound or other insulation material/medium.

Abstract: An optoelectronic element includes an optoelectronic unit having a first top surface; a first metal layer on the first top surface; a first transparent structure surrounding the optoelectronic unit and exposing the first top surface; and a first contact layer on the first transparent structure, including a connective part electrically connected with the first metal layer.

Abstract: Disclosed are a light emitting device package and a light unit including the same. The light emitting device package includes a body; a first lead frame having a first cavity in a first region of the body; a second lead frame having a second cavity in a second region of the body; a first bonding part adjacent to a first lateral side of the body and extended from the first cavity of the first lead frame; a second bonding part adjacent to a second lateral side of the body, which is opposite to the first lateral side of the body, and extended from the second cavity of the second lead frame; a first light emitting device in the first cavity; a second light emitting device in the second cavity; a third cavity adjacent to the first bonding part; a first protective device in the third cavity.

Abstract: An optoelectronic package includes an optoelectronic chip, a transparent protection layer and a plurality of pads. The optoelectronic chip has an upper surface and an active area defined on the upper surface. The transparent protection layer is connected to the optoelectronic chip and covers the upper surface. The transparent protection layer touches and is entirely attached to the active area. The pads are electrically connected to the optoelectronic chip.

Abstract: An optical semiconductor element mounting package that has good adhesion between the resin molding and the lead electrodes and has excellent reliability is provided, as well as an optical semiconductor device using the package is also provided. The optical semiconductor element mounting package having a recessed part that serves as an optical semiconductor element mounting region, wherein the package is formed by integrating: a resin molding composed of a thermosetting light-reflecting resin composition, which forms at least the side faces of the recessed part; and at least a pair of positive and negative lead electrodes disposed opposite each other so as to form part of the bottom face of the recessed part, and there is no gap at a joint face between the resin molding and the lead electrodes.

Abstract: A space between a lower substrate and an upper substrate including an organic EL light-emitting layer which includes a display region for displaying an image is filled by a dam material which is applied to enclose an exterior edge of the display region and a filling material which is dripped into the interior side of the dam material. The dam material is an epoxy resin with a comparatively high viscosity before hardening and the filling material is an epoxy resin with a comparatively low viscosity before hardening. A substrate concave part is formed between the display region on a surface of the lower substrate and a coating region of the dam material.

Abstract: Provided are a light source circuit unit that improves light extraction efficiency, as well as an illuminator and a display that include such a light source circuit unit. The light source circuit unit includes: a circuit substrate having a wiring pattern on a surface thereof, the wiring pattern having light reflectivity, a circular pedestal provided on the circuit substrate, a water-repelling region provided at least from a peripheral edge portion of the pedestal to a part of a side face of the pedestal, and one or two or more light-emitting device chips mounted on the pedestal, and driven by a current that flows through the wiring pattern.

Abstract: A method of producing an optoelectronic semiconductor chip includes providing a semiconductor layer sequence with at least one active layer, providing a one-piece conversion medium body, wherein a matrix material is incompletely crosslinked and/or cured, and wherein the conversion medium body exhibits at room temperature a hardness of Shore A 0 to Shore A 35 and/or a viscosity of 10 Pa·s to 150 Pa·s, placing the conversion medium body onto the semiconductor layer sequence such that they are in direct contact with one another, and curing the conversion medium body wherein after curing the hardness of the conversion medium body is Shore A 30 to Shore D 80.

Abstract: Disclosed are an epoxy resin composition and a light emitting apparatus. The epoxy resin composition includes a triazine derivative epoxy resin and a silicon-containing alicyclic epoxy resin.

Abstract: A method of manufacturing an LED lighting arrangement, comprises: receiving an optical component having a diffusing material that is light diffusive and at least one photoluminescent material that is excitable by light of a first wavelength range and which emits light of a second wavelength range; receiving an LED assembly that is operable to generate the light of the first wavelength range and mounting the optical component to the LED assembly to form the LED lighting arrangement. The optical component having the diffusing and photoluminescent materials is mass produced separately from the LED assembly and can be selected such that light generated by the optical component combined with the light generated by the LED assembly corresponds to light of a selected color. Also disclosed are LED lighting arrangements, components for LED lighting arrangements and methods of fabricating an optical component.

Abstract: One purpose is to provide a silicone resin composition which provides a cured product having a large Abbe's number and a high brightness. A silicone resin composition including (A-1) an organopolysiloxane having a three-dimensional crosslinked structure, at least two alkenyl groups, and at least one monovalent aromatic hydrocarbon group bonded to a silicon atom, (A-2) a linear organopolysiloxane having alkenyl groups at at least both terminals of a molecular chain and at least one monovalent aromatic hydrocarbon group bonded to a silicon atom, (B-1) a linear organohydrogen polysiloxane having at least one silphenylene skeleton in a molecular chain and hydrosilyl groups at least both terminals of the molecular chain, in an amount such that a ratio of the number of the hydrosilyl groups in component (B-1) to a total number of the alkenyl groups in components (A-1) and (A-2) is 0.5 to 2, and (C) a hydrosilylation catalyst in a catalytic amount.

Abstract: Provided is a light emitting device. The light emitting device includes a plurality of metal layers spaced from each other, a first insulation film having an opened area in which a portion of the plurality of metal layers is opened, the first insulation film being disposed around top surfaces of the plurality of metal layers, a light emitting chip disposed on at least one of the plurality of metal layers, the light emitting chip being electrically connected to the other metal layer, a resin layer disposed on the plurality of metal layers and the light emitting chip, and a first guide member formed of a non-metallic material, the first guide member being disposed on the first insulation film.

Abstract: A method of and a system for making LED comprising concurrently forming multiple dam structures on a whole silicon wafer using a liquid transfer mold, attaching dies to the silicon wafer inside each of the dam structure, performing flux reflow, cleaning flux, performing wire bonding, dispensing phosphor, curing the phosphor, concurrently forming dome structures by using a liquid transfer mold on all of the dam structures, mounting wafer, and using a saw for single or multiple LED(s) singulation.

Abstract: An exemplary embodiment described technology relates generally to an organic light emitting diode (OLED) display and a manufacturing method thereof. The organic light emitting diode (OLED) display according to an exemplary embodiment includes: a substrate; an encapsulation member; an organic light emitting element between the substrate and the encapsulation member; a middle sealing member including one side disposed between the substrate and the encapsulation member and another side extended from the one side to be bent and enclosing an edge of the encapsulation member; a first sealant sealing and combining the one side of the middle sealing member and the substrate to each other; a second sealant sealing and combining the other side of the middle sealing member and the encapsulation member to each other; and a getter at the one side of the middle sealing member and the encapsulation member.

Abstract: A transparent LED wafer module and a method for manufacturing the same are provided. In a conductor LED device epitaxial process, the conductor LED device is grown on a transparent material wafer, where both surfaces of the conductor LED device are entirely grown on the transparent material, and then a transparent glass substrate is restacked, thereby securing a high amount of light.

Abstract: An exemplary embodiment of the present invention includes a light emitting diode including a strain-enhanced well layer. The light emitting diode includes an n-contact layer, an active layer having a barrier layer and a well layer, a p-contact layer, and a strain-enhancing layer configured to enhance a strain applied to the well layer.

Abstract: Provided are a light emitting device, a method for fabricating the light emitting device, and a light emitting device package. The light emitting device includes a light emitting structure including a first conductive type semiconductor layer, an active layer under the first conductive type semiconductor layer, and a second conductive type semiconductor layer under the active layer, a conductive support member, and a protection member on the light emitting structure. The light emitting structure has a first width and a second width. A difference between the first width and the second width defines a stepped structure or an inclined structure. The protection member is disposed on the stepped or the inclined structure defined by the difference between the first and second widths of the light emitting structure.

Abstract: Provided are a curable composition and its use. The curable composition has excellent processability, workability and adhesiveness, exhibits excellent light extraction efficiency, crack resistance, hardness, thermal and shock resistance and adhesiveness after curing, has long-lasting durability and reliability even under harsh conditions, and does not cause whitening or surface stickiness. The curable composition can be used as an encapsulant or adhesive material for an optical semiconductor such as an LED.

Abstract: The present invention provides a polycarbosilane represented by the following formula (1): [R1R2R3SiX1/2]M[R4R5SiX2/2]D[R6SiX3/2]T[SiX4/2]Q??(1); and a curable composition comprising: (A) said polycarbosilane of formula 1 as polycarbosilane A, (B) at least one polycarbosilane B represented by the following formula (2): [R7R8R9SiX1/2]M?[R10R11SiX2/2]D?[R12SiX3/2]T?[SiX4/2]Q?,??(2), and (C) at least a catalyst.

Abstract: LED chips and packages are disclosed having lenses made of materials that resist degradation at higher operation temperatures and humidity, and methods of fabricating the same. The lenses can be made of certain materials that can withstand high temperatures and high humidity, with the lenses mounted to the LED prior to certain critical metallization steps. This helps avoid damage to the metalized part that might occur as a result of the high mounting or bonding temperature for the lens. One embodiment of an LED chip comprises a flip-chip LED and a lens mounted to the topmost surface of the flip-chip LED. Lenses can be bonded to LEDs at the wafer level or at the chip level. Some of the LED chips and packages can have lenses of different materials with planar and/or curved surfaces.

Abstract: An organic light-emitting display device and a method of manufacturing the same are disclosed. The organic light-emitting display device includes: a substrate, a plurality of pixels on the substrate, a plurality of first electrodes, each disposed in each of the plurality of pixels, a pixel defining layer including a first pixel defining sub-layer disposed between each two adjacent first electrodes, and a second pixel defining sub-layer covering the first pixel defining sub-layer and surface edge portions of each two adjacent first electrodes, an intermediate layer disposed on each of the first electrodes and including an emission layer, and a second electrode configured to face the first electrodes.

Abstract: A light emitting device (LED) package includes a submount and a light emitting chip. The submount has a chip region and a supporting region over which the chip is mounted, and an encapsulating material and fluorescent material are formed over the chip. The coverage area of encapsulating and fluorescent materials is substantially coextensive with the chip or chip region, and a first area between an edge of the chip region and an edge of the supporting region is greater than a second area between the edge of the chip region and the chip.

Abstract: This invention provides a light-emitting chip device with high thermal conductivity, which includes an epitaxial chip, an electrode disposed on a top surface of the epitaxial chip and a U-shaped electrode base cooperating with the electrode to provide electric energy to the epitaxial chip for generating light by electric-optical effect. The epitaxial chip includes a substrate and an epitaxial-layer structure with a roughening top surface and a roughening bottom surface for improving light extracted out of the epitaxial chip. A thermal conductive transparent reflective layer is formed between the substrate and the epitaxial-layer structure. The electrode base surrounds the substrate, the transparent reflective layer and a first cladding layer of the epitaxial-layer structure to facilitate the dissipation of the internal waste heat generated when the epitaxial chip emitting light. A method for manufacturing the chip device of the present invention is provided.