Abstract: A semiconductor light-emitting structure includes a silicon substrate, a distributed Bragg reflector, a semiconductor structures layer and an epitaxy connecting layer. The silicon substrate has a top surface. The distributed Bragg reflector is formed on the top surface of the silicon substrate. The semiconductor structures layer is configured for emitting light. The epitaxy connecting layer is placed between the distributed Bragg reflector and the semiconductor structures layer. Grooves extend from the semiconductor structures layer through the epitaxy connecting layer and the distributed Bragg reflector to reach the semiconductor structures layer.

Abstract: An exemplary LED package includes first and second electrodes, an LED chip and two electrically conductive wires. The first electrode has a top surface and an opposite bottom surface. A recess is defined in the top surface of the first electrode. The second electrode has a top surface and an opposite bottom surface. A recess is defined in the top surface of the second electrode. The LED chip has a bottom surface attached to the top surface of the first electrode, and a top surface on which a first pad and a second pad are formed. One of the electrically conductive wires has an end connecting to the first pad and an opposite end joining with a bottom of the recess of the first electrode. The other has an end connecting to the second pad and an opposite end joining with a bottom of the recess of the second electrode.

Abstract: An LED package includes a substrate, an LED chip and an encapsulation. The substrate includes a main plate, and a first soldering pad and a second soldering pad attached to the main plate. The first soldering pad and the second soldering pad are separated from each other. The LED chip includes a first electrode and a second electrode. The LED chip is mounted on the substrate with the second electrode electrically connected to the second soldering pad of the substrate. The encapsulation includes a main body enclosing the LED chip and an electric connecting unit electrically connecting the first electrode of the LED chip and the first soldering pad.

Abstract: An LED package includes a substrate, an LED die, electrodes, a reflective cup, a barrier portion and an encapsulation. The substrate includes a first surface and a second surface opposite to the first surface. The electrodes are formed on the substrate and spaced from each other. The barrier portion is formed on the electrodes and covered by the reflective cup, wherein a bonding force between the barrier portion and the electrodes is larger than that between the reflective cup and the electrodes. The LED die is mounted on one of the electrodes, received in the reflective cup and electrically connected to the electrodes via wire bonding. The disclosure also provides a method for making an LED package.

Abstract: A method for fabricating a semiconductor lighting chip includes steps of: providing a substrate; forming a first etching layer on the substrate; forming a connecting layer on the first etching layer; forming a second etching layer on the connecting layer; forming a lighting structure on the second etching layer; and etching the first etching layer, the connecting layer, the second etching layer and the lighting structure, wherein an etching rate of the first etching layer and the second etching layer is lager than that of the connecting layer and the lighting structure, thereby to form the connecting layer and the lighting structure each with an inverted frustum-shaped structure.

Abstract: A lateral thermal dissipation LED and a fabrication method thereof are provided. The lateral thermal dissipation LED utilizes a patterned metal layer and a lateral heat spreading layer to transfer heat out of the LED. The thermal dissipation efficiency of the LED is increased, and the lighting emitting efficiency is accordingly improved.

Abstract: An exemplary light emitting diode (LED) package includes a substrate having a first electrical portion and a second electrical portion formed thereon, two antioxidation layers formed on and electrically connected to the first electrical portion and the second electrical portion, respectively, and an LED chip disposed on the substrate and electrically connected to the two antioxidation layers.

Abstract: An LED unit includes an LED and an optical element. The LED includes a substrate, an LED chip fixed on the substrate and an encapsulation encapsulating the LED chip. The LED further includes a first magnet fixed on the substrate. The optical element includes an optical adjustment layer and a second magnet. The second magnet attracts the first magnet to fix the optical element on the LED. The LED unit can be adjusted to have different optical characteristics by replacing the optical element thereof with another optical element.

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 formed on the substrate in sequence, the connecting layer being etchable by alkaline solution, a bottom surface of the second n-type GaN layer facing towards the connecting layer having a roughened exposed portion, the GaN on the bottom surface of the second n-type GaN layer having an N-face polarity, a blind hole extending through the p-type GaN layer, the light emitting layer and the second n-type GaN layer to expose the connecting layer, and an annular rough portion formed on the bottom surface of the second n-type GaN layer and surrounding each blind hole.

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: A semiconductor structure includes a Si substrate, a supporting layer and a blocking layer formed on the substrate and an epitaxy layer formed on the supporting layer. The supporting layer defines a plurality of grooves therein to receive the blocking layer. The epitaxy layer is grown from the supporting layer. A plurality of slots is defined in the epitaxy layer and over the blocking layer. The epitaxy layer includes an N-type semiconductor layer, a light-emitting layer and a P-type semiconductor layer. A method for manufacturing the semiconductor structure is also disclosed.

Abstract: A light emitting diode (LED) device includes a substrate, first and second LED chips arranged on the substrate, and a phosphor layer over the first and second LED chips. The phosphor layer includes a plurality of phosphor units, each including a phosphor particle and a silver halide layer encapsulating the phosphor particle. Light emitted from the second LED chip strikes the phosphor particles to generate a first light, which. combines with the light to generate a resultant light. The silver halide layer is reduced by the light from the first LED chip to produce silver particles around the phosphor particles. The silver particles can block the light emitted from the second LED chip from sticking the phosphor particles. By adjusting the current supplied to the first LED chip, the color temperature of the resultant light generated by the LED device can be changed.

Abstract: An LED package includes a substrate, an LED chip, a bounding dam, and a first encapsulation. The substrate includes a first surface and a second surface opposite to the first surface. The LED chip is mounted on the first surface of the substrate. The bounding dam is formed on the first surface of the substrate and surrounds the LED chip. The bounding dam and the substrate cooperatively define a receiving space. The bounding dam is made of thermoset resin. The first encapsulation is formed in the receiving space and encloses the LED chip.

Abstract: A light-emitting diode comprises a light-emitting diode chip having a first semiconductor layer, a first electrode, an active layer formed on the first semiconductor layer, a second semiconductor layer formed on the active layer and a second electrode formed on the second semiconductor layer. The first semiconductor layer, the active layer, the second semiconductor layer and the second electrode sequentially compose a stacked multilayer. A blind hole penetrates the second electrode, the second semiconductor layer, the active layer and inside the first semiconductor layer. The first electrode is disposed on the first semiconductor layer inside the blind hole. A first supporting layer and a second supporting layer are respectively disposed on the first electrode and the second electrode, wherein the first supporting layer and the second supporting layer are separated from each other. A method for manufacturing the light-emitting diode is also provided in the disclosure.

Abstract: An LED includes a base, a pair of leads fixed on the base, a housing fixed on the leads, a chip mounted on one lead and an encapsulant sealing the chip. The housing defines a cavity in a central area thereof and a chamber adjacent to a circumferential periphery thereof. Top faces of the leads are exposed in the chamber. A blocking wall is formed in the chamber to contact the exposed top faces of the leads. A bonding force between the blocking wall and the leads is larger than that between the leads and the housing. A method for manufacturing the LED is also disclosed.

Abstract: An LED package includes a substrate, an LED chip, and an encapsulation. The substrate includes a first surface. The LED chip is mounted on the first surface of the substrate. The encapsulation covers the LED chip. The encapsulation includes a transparent main body and a number of carbon nanotubes distributed in the transparent main body; the carbon nanotubes are arranged substantially extending along a same direction whereby light generated by the LED chip is polarized prior to radiation out of the encapsulation.

Abstract: A light emitting diode package comprises a light emitting diode chip, a first luminescent conversion layer and a separate second luminescent conversion layer on the first luminescent conversion layer. The first luminescent conversion layer has a first luminescent conversion element surrounding the light emitting diode chip. The second luminescent conversion layer has a second luminescent conversion element located above the light emitting diode chip. An excitation efficiency of the first luminescent conversion element is higher than that of the second luminescent conversion element.

Abstract: A method for manufacturing an LED package, comprising steps of: providing a substrate, the substrate forming a plurality of spaced rough areas on a surface thereof, each of the rough areas forming a rough structure thereon, a block layer being provided on a remaining part of the surface of the substrate relative to the rough areas; forming a metal layer on a top surface of each rough structure; forming a reflector on the substrate, the reflector defining a cavity and surrounding two adjacent metal layers; arranging an LED chip in the cavity, the LED chip electrically connecting to the two adjacent metal layers; forming an encapsulation layer in the cavity to seal the LED; and separating the substrate from the metal layers, the encapsulation layer and the reflector.

Abstract: An LED package includes a substrate with two opposite lateral bulging portions, an LED die, an electrode structure, and a reflective layer. The substrate includes a first substrate and a second substrate stacked together; the first substrate and the second substrate are transparent; and the substrate includes an emitting surface for emitting light of the LED package. The electrode structure is sandwiched between the first substrate and the second substrate. The LED die is mounted in the substrate and electrically connected to the electrode structure. The reflective layer is formed on an outer surface of the substrate except the emitting surface and the bulging portions. The disclosure also provides a method for manufacturing such an LED package.

Abstract: A method for fabricating flip-chip semiconductor optoelectronic devices initially flip-chip bonds a semiconductor optoelectronic chip attached to an epitaxial substrate to a packaging substrate. The epitaxial substrate is then separated using lift-off technology.