Abstract: An exemplary light emitting diode includes a first type semiconductor layer, a second type semiconductor layer, and a multi quantum well layer sandwiched between the first and second type semiconductor layers. The multi quantum well layer includes a first barrier layer, a second barrier layer, two well layers sandwiched between the first and second barrier layers, and a third barrier layer sandwiched between the two well layers. The first and second barrier layers each have an energy level of conduction band higher than that of the third barrier layer. The first and second barrier layers each have an energy level of valence band higher than that of the third barrier layer.

Abstract: An LED light source device includes an LED light source, a first translucent structure covering the LED light source and a second translucent structure covering the first translucent structure. An interior of the first translucent structure has light scattering powder distributed therein. The LED light source is embedded in the first translucent structure. The LED light source is covered by the light scattering powder. The second translucent structure has a radius of R and an index of refraction of N1, while the first translucent structure has a radius of r, wherein R, r and N1 satisfy the following relation: N1<R/(2r?R).

Abstract: A method for manufacturing an LED package includes providing a substrate including an insulating layer inlayed with first and second electrodes. The first and second electrodes define a chip fastening area. An LED chip is fastened on the chip fastening area and electrically connected to the first and second electrodes. A buffer layer including a shelter and grooves is brought to be located over the substrate wherein the shelter covers the chip fastening area and the grooves are located over portions of the substrate beside the first and second electrodes. A reflecting layer is formed in the grooves of the buffer layer by injecting liquid material into the grooves. The buffer layer is removed after the liquid material is solidified and a through hole is defined. An encapsulant is formed to cover the LED chip by injecting the encapsulant into the through hole and the chip fastening area.

Abstract: An exemplary method for manufacturing an LED package includes following steps: providing a substrate; forming a reflector on the substrate with a receiving chamber defined in the reflector; providing an LED chip and mounting the LED chip on the substrate wherein the LED chip is received in the receiving chamber; providing a gelatinous phosphor layer and arranging the gelatinous phosphor layer on a top end of the reflector wherein the gelatinous phosphor layer covers the receiving chamber and phosphor powder is evenly distributed in the gelatinous phosphor layer; providing a pressing mold and arranging the pressing mold on a top end of the gelatinous phosphor layer; pressing the pressing mold toward the gelatinous phosphor layer to make the gelatinous phosphor layer fill in the receiving chamber; solidifying the gelatinous phosphor layer.

Abstract: A light emitting diode (LED) comprises a substrate, an epitaxial layer and an aluminum nitride (AlN) layer sequentially disposed on the substrate. The AlN layer comprises a plurality of stacks separated from each other, wherein the epitaxial layer entirely covers the plurality of stacks of the AlN layer. The AlN layer with a plurality of stacks reflects upwardly light generated by the epitaxial layer and downwardly toward the substrate to an outside of LED through a top plan of the LED. A method for forming the LED is also disclosed.

Abstract: An LED includes a substrate, a first n-type GaN layer, a connecting layer, a second n-type GaN layer, a light emitting layer, and a p-type GaN layer. The first n-type GaN layer, the connecting layer, and the second n-type GaN layer are formed on the substrate in sequence. The connecting layer is etchable by alkaline solution, and a bottom surface of the second n-type GaN layer facing towards the connecting layer has a roughed exposed portion. The GaN on the bottom surface of the second n-type GaN layer is N-face GaN. A top surface of the second n-type GaN layer facing away from the connecting layer includes a first area and a second area. The light emitting layer and the p-type GaN layer are formed on the first area of the top surface of the second n-type GaN layer in sequence.

Abstract: An LED package includes a substrate, an LED chip arranged on the substrate, and a light transmission layer arranged on a light output path of the LED chip. The substrate includes a first electrode and a second electrode separated and electrically insulated from the first electrode. The LED chip is electrically connected to the first electrode and the second electrode of the substrate. The light transmission layer comprises two parallel transparent plates and a fluorescent layer sandwiched between the two transparent plates. The LED package further includes an encapsulation layer sealing the LED chip therein. The light transmission layer is directly located on a top surface of each LED chip, and the encapsulation layer seals the light transmission layer therein.

Abstract: A multi-quantum well structure includes two first barrier layers, two well layers sandwiched between the two first barrier layers, and a doped second barrier layer sandwiched between the two well layers. The second barrier layer has its conduction band and forbidden band gradually transiting to those of one of the well layers, and a dopant concentration of the second barrier layer gradually changes along a direction from one well layer to the other. The invention also relates to a light emitting diode structure having the multi-quantum well structure.

Abstract: An LED package includes a light transmissive encapsulation, an LED die embedded in the encapsulation from a bottom surface of the encapsulation, a positive electrode electrically connected to an anode of the LED die, and a negative electrode electrically connected to a cathode of the LED die. The encapsulation includes a light emitting surface opposite to the bottom surface thereof. The LED die includes a front surface for outputting light outward, and a back surface opposite to the front surface. The front surface is covered by the encapsulation and faces the light emitting surface of the encapsulation. The back surface is exposed outside. A light emitting device is provided by mounting the LED package to a circuit board. The circuit board has a heat conductor connecting with the LED die.

Abstract: A method for packaging an LED, includes steps: providing a supporting board and then dripping a gel mixed with fluorescent therein on the supporting board; scraping the gel over the supporting board with a scraper form a gelatinous fluorescent film on the supporting board, and solidifying the gelatinous fluorescent film pieces to form a solidified fluorescent film; cutting the solidified fluorescent film into individual pieces, and peeling the solid fluorescent films from the supporting board; attaching one piece of the fluorescent film on a light outputting surface of an LED die; mounting the LED die on a substrate, and electrically connecting the LED die to the circuit structure; and forming an encapsulation on the substrate to cover the LED die.

Abstract: A method of manufacturing an LED package including steps: providing an electrode, the electrode including a first electrode, a second electrode, a channel defined between the first electrode and the second electrode, the first electrode and the second electrode arranged with intervals mutually, a cavity arranged on the first electrode, and the cavity communicating with the channel; arranging an LED chip electrically connecting with the first electrode and the second electrode and arranged inside the cavity; providing a shield covering the first electrode and the second electrode; injecting a transparent insulating material to the cavity via the channel, and the first electrode, the second electrode, and the shield being interconnected by the transparent insulating material; solidifying the transparent insulating material to obtain the LED package.

Abstract: An exemplary light-emitting diode (LED) includes a substrate, a first electrode and a second electrode sandwiching the substrate therebetween, an LED chip electrically connected to the first electrode and the second electrode, a reflector located on the first electrode and the second electrode and surrounding the LED chip, and a first retaining wall mounted on an edge of the first electrode and a second retaining wall mounted on an edge of the second electrode. The first retaining wall and the second retaining wall are made of conductive material. The first retaining wall and the second retaining wall are at a same side of the LED. Outer surfaces of the first retaining wall and the second retaining wall are exposed out of the reflector.

Abstract: A light emitting diode (LED) includes a substrate, an electrode structure positioned on the substrate, an LED component electrically connected to the electrode structure, and a lens structure positioned on the substrate and covering the LED component. The lens structure includes a rugged structure adjacent to the substrate; the roughness of the rugged structure decreases gradually along a direction from a center of the lens structure center toward a peripheral edge thereof. The present disclosure also provides a method for manufacturing the LED light source.

Abstract: A method for manufacturing an LED package comprising steps of: providing a substrate and forming spaced electrode structures on the substrate; providing a mold on the top surface of the substrate wherein the mold defines spaced annular grooves which cooperate with the top surface of the substrate to define cavities; filling the cavities with metal material; removing the mold and hardening the metal material to form reflection cups wherein each reflection cup surrounds a corresponding electrode structure and defines a recess; polishing surfaces of the reflection cups and the electrode structures; arranging LED chips in the recesses with each LED chip electrically connected to the electrode structure; injecting an encapsulation layer in the recesses to seal the LED chips; and cutting the substrate to obtain individual LED packages.

Abstract: An exemplary LED module includes an LED and a lens covering the LED. The lens includes a light-guiding portion over the LED and retaining portions protruding downwardly from the light-guiding portion. The LED includes a substrate, a first electrode and a second electrode mounted on the substrate, and an LED chip electrically connecting the first electrode and the second electrode respectively. Through holes are defined in the first electrode and the second electrode, respectively. Each retaining portion includes a first rugged portion and a second rugged portion. The retaining portions are inserted into the through holes correspondingly, the first rugged portion connects glue filled in a corresponding through hole, and the second rugged portion abuts the substrate, whereby the lens and the substrate are securely connected together.

Abstract: A method for manufacturing an LED package includes following steps: providing a base with an LED chip mounted on the base; providing a porous carrier with a plurality of holes, and disposing the base on the porous carrier; providing a film with a phosphor layer attached on the film; providing a mold, and putting the porous carrier, the base, the LED chip, and the film into the mold; extracting air from the mold to an external environment through the holes of the porous carrier, and/or, blowing air toward the film to urge the film to move toward the LED chip, resulting in that the film is conformably attached onto the LED chip and the base; and solidifying the phosphor layer on the LED chip by means of heating whereby the phosphor is conformably and securely attached on the LED chip.

Abstract: A structure of semiconductor device includes a first semiconductor layer; an intermediate layer on a surface of said first semiconductor layer; a second semiconductor layer on said intermediate layer, wherein said intermediate layer and said second semiconductor layer are integrated to a set of sub-structures; and a semiconductor light emitting device on said second semiconductor layer.

Abstract: An light-emitting diode (LED) package includes a substrate, a electrode structure embedded in the substrate, and a plurality of LED chips electrically connecting with the electrode structure. The substrate includes a main portion and a protruding portion extending from a bottom surface of the main portion. The main portion is located above the protruding portion. The electrode structure includes a first, a second and a third electrode spaced from each other. The third electrode is located between the first and second electrodes. Top surfaces of the first, second and third electrodes are exposed out of the top surface of the main portion. Bottom surfaces of the first and second electrodes are exposed out of the bottom surface of the main portion. Bottom surface of the third electrode is covered by the protruding portion. The present disclosure also relates to a method for manufacturing the LED package.

Abstract: A method for manufacturing a light emitting diode chip includes the following steps: providing an epitaxial structure having an epitaxial layer; forming a first electrode and a second electrode on the epitaxial layer; coating an inert layer on the epitaxial structure, the first electrode and the second electrode continuously; annealing the first electrode and the second electrode; and removing the inert layer coated on the first electrode and the second electrode to expose the first electrode and the second electrode.

Abstract: A method for manufacturing an LED package structure is disclosed wherein a substrate with a first electrode, a second electrode and a connecting layer is provided. A photoresist coating is provided to cover the substrate, the first electrode, the second electrode and the connecting layer. A portion of the photoresist coating is removed to define a groove corresponding to the connecting layer. A metal layer is formed in the groove to join the connecting layer. A remaining portion of the photoresist coating is removed and a concave is formed and surrounded by the metal layer. A reflective layer is formed on an inside surface of the concave to join the metal layer to form a reflective cup. An LED die is mounted in the reflective cup and electrically connects with the first and second electrodes.