Abstract: An exemplary light emitting diode includes a substrate and a first undoped GaN layer formed on the substrate. The first undoped GaN layer has ion implanted areas on an upper surface thereof. A plurality of second undoped GaN layers is formed on the first undoped GaN layer. Each of the second undoped GaN layers is island shaped and partly covers at least one corresponding ion implanted area. A Bragg reflective layer is formed on the second undoped GaN layer and on portions of upper surfaces of the ion implanted areas not covered by the second undoped GaN layers. An n-type GaN layer, an active layer and a p-type GaN layer are formed on an upper surface of the Bragg reflective layer in that sequence. A method for manufacturing the light emitting diode is also provided.

Abstract: A manufacturing method for an LED includes providing a substrate having a buffer layer and a first N-type epitaxial layer, forming a blocking layer on the first N-type epitaxial layer, and etching the blocking layer to form patterned grooves penetrating the blocking layer to the first N-type epitaxial layer. A second N-type epitaxial layer is then formed on the blocking layer to contact the first N-type epitaxial layer; a light emitting layer, a P-type epitaxial layer and a conductive layer are thereafter disposed on the second N-type epitaxial layer; an N-type electrode is formed to electrically connect with the first N-type epitaxial layer, and a P-type electrode is formed on the conductive layer. The N-type electrode is disposed on the blocking layer and separated from the second N-type epitaxial layer and has a portion extending into the patterned grooves to contact the first N-type epitaxial layer.

Abstract: A method of detecting hepatocellular carcinoma includes the steps of: detecting a methylation level of a CpG site of HOXA9 gene in a biological sample taken from a suspected subject; and comparing the methylation level to a reference methylation level of a CpG site of HOXA9 gene in another biological sample taken from a normal subject not suffering from hepatocellular carcinoma, wherein when the methylation level is higher than the reference methylation level, the suspected subject is likely to suffer from hepatocellular carcinoma, and wherein each of the biological samples is selected from the group consisting of a blood sample, a serum sample, and a plasma sample.

Abstract: An exemplary LED includes an electrode layer, an LED die, a transparent electrically conductive layer, and an electrically insulating layer. The electrode layer includes a first section and a second section electrically insulated from the first section. The LED die is arranged on and electrically connected to the second section of the electrode layer. The transparent electrically conductive layer is formed on the LED die and electrically connects the LED die to the first section of the electrode layer. The electrically insulating layer is located between the LED die and the transparent electrically conductive layer to insulate the transparent electrically conductive layer from the second section of the electrode layer.

Abstract: An LED package includes a substrate, a buffer layer formed on the substrate, an epitaxial structure formed on the buffer layer, and a plurality of carbon nanotube bundles formed in the epitaxial structure.

Abstract: An LED comprises a substrate, a buffer layer, an epitaxial layer and a conductive layer. The epitaxial layer comprises a first N-type epitaxial layer, a second N-type epitaxial layer, and a blocking layer with patterned grooves sandwiched between the first and second N-type epitaxial layers. The first and second N-type epitaxial layers make contact each other via the patterned grooves. Therefore, the LED enjoys a uniform current distribution and a larger light emitting area. A manufacturing method for the LED is also provided.

Abstract: An LED epitaxial structure includes a substrate, a buffer layer, a functional layer and a light generating layer. The buffer layer is located on a top surface of the substrate. The functional layer includes a plurality of high-temperature epitaxial layers and low-temperature epitaxial layers alternatively arranged between the buffer layer and light generating layer. A textured structure is formed in the low-temperature epitaxial layer. A SiO2 layer including a plurality of convexes is located on the textured structure to increase light extraction efficiency of the LED epitaxial structure. A manufacturing method of the LED epitaxial structure is also disclosed.

Abstract: A method for manufacturing a light emitting diode chip includes following steps: providing a sapphire substrate, the sapphire substrate having a plurality of protrusions on an upper surface thereof; forming an un-doped GaN layer on the upper surface of the sapphire substrate, the un-doped GaN layer totally covering the protrusions; forming a plurality of semiconductor islands on an upper surface of the un-doped GaN layer by self-organized growth, gaps being formed between two adjacent semiconductor islands to expose a part of the upper surface of the un-doped GaN layer; forming an n-type GaN layer on the exposed part of the upper surface of the un-doped GaN layer, the n-type GaN layer being laterally grown to totally cover the semiconductor islands; forming an active layer on an upper surface of the n-type GaN layer; and forming a p-type GaN layer on the active layer.

Abstract: A method for manufacturing a light emitting diode chip includes following steps: providing a sapphire substrate, the sapphire substrate having a plurality of protrusions on an upper surface thereof; forming an un-doped GaN layer on the upper surface of the sapphire substrate, the un-doped GaN layer having an upper part covering top ends of the protrusions; forming a distributed bragg reflective layer on the un-doped GaN layer until the distributed bragg reflective layer totally covering the protrusions and the un-doped GaN layer; etching the distributed bragg reflective layer and the upper part of the un-doped GaN layer to expose the top ends of the protrusions; and forming an n-type GaN layer, an active layer, and a p-type GaN layer sequentially on the top ends of the protrusions and the distributed bragg reflective layer. An LED chip formed by the method described above is also provided.

Abstract: A light emitting diode chip includes a sapphire substrate and a plurality of carbon nano-tubes arranged on an upper surface of the sapphire substrate. Gaps are formed between two adjacent carbon nano-tubes to expose parts of the upper surface of the sapphire substrate. An un-doped GaN layer is formed on the exposed parts of the upper surface of the sapphire substrate and covers the carbon nano-tubes. An n-type GaN layer, an active layer and a p-type GaN layer are formed on the un-doped GaN layer in sequence. A method for manufacturing the light emitting diode chip is also provided.

Abstract: A method for making a light emitting diode chip includes following steps: providing a sapphire substrate, the sapphire substrate having a plurality of protrusions on an upper surface thereof; forming an un-doped GaN layer on the upper surface of the sapphire substrate, the un-doped GaN layer partly covering the protrusions to expose a part of each of the protrusions; etching the un-doped GaN layer to expose a top end of each of the protrusions; and forming an n-type GaN layer, an active layer, and a p-type GaN layer sequentially on the top ends of the protrusions and the un-doped GaN layer.

Abstract: An LED manufacturing method includes following steps: providing an LED die; providing an electrode layer having a first section and a second section electrically insulated from the first section, and arranging the LED die on the second section wherein an electrically conductive material electrical connects a bottom of the LED die with second section; forming a transparent conductive layer to electrically connect a top of the LED die with the first section; providing a base and coating an outer surface of the base with a layer of electrically conductive material, defining a continuous gap in the electrically conductive material to divide the electrically conductive material into a first electrode part, and a second electrode part, arranging the electrode layer on the base so that the first section contacts the first electrode part, and the second section contacts the second electrode part.

Abstract: A method for epitaxial growth of a light emitting diode, includes following steps: providing a substrate; forming a buffer layer on the substrate; forming a first epitaxial layer on the buffer layer in a first temperature; forming a second epitaxial layer on the first epitaxial layer in a second temperature lower than the first temperature, thereby forming a first rough surface on the second epitaxial layer; etching the second epitaxial layer and the first epitaxial layer until a second rough surface is formed on the first epitaxial layer; forming a mask layer on the rough surface of the first epitaxial layer; partly etching the mask layer to form a plurality of protrusions with the first epitaxial layer exposed thereamong; and forming an N-type epitaxial layer, an active layer and a P-type epitaxial layer on the first epitaxial layer in sequence.

Abstract: A manufacturing method for an LED (light emitting diode) includes following steps: providing a substrate; disposing a transitional layer on the substrate, the transitional layer comprising a planar area with a flat top surface and a patterned area with a rugged top surface; coating an aluminum layer on the transitional layer; using a nitriding process on the aluminum layer to form an AlN material on the transitional layer; disposing an epitaxial layer on the transitional layer and covering the AlN material, the epitaxial layer contacting the planar area and the patterned area of the transitional layer, a plurality of gaps being defined between the epitaxial layer and the slugs of the second part of the AlN material in the patterned area of the transitional layer.

Abstract: An exemplary method of manufacturing a light emitting diode (LED) die includes steps: providing a preformed LED structure, the LED structure including a first substrate, and a nucleation layer, a buffer layer, an N-type layer, a muti-quantum well layer and an P-type layer formed successively on the first substrate; forming at least one insulation block on the P-type layer; forming a mirror layer on the on the P-type layer and covering the insulation block; forming a conductive second substrate on the mirror layer; removing the first substrate, the nucleation layer and the buffer layer and exposing a bottom surface of the N-type layer; and disposing one N-electrode on the exposed surface of the N-type layer. The N-electrode is located corresponding to the insulation block.

Abstract: An LED comprises an electrode layer comprising a first a second sections electrically insulated from each other; an electrically conductive layer on the second section, an electrically conductive pole protruding from the electrically conductive layer; an LED die comprising an electrically insulating substrate on the electrically conductive layer, and a P-N junction on the electrically insulating substrate, the P-N junction comprising a first electrode and a second electrode, the electrically conductive pole extending through the electrically insulating substrate to electrically connect the first electrode to the second section; a transparent electrically conducting layer on the LED die, the transparent electrically conducting layer electrically connecting the second electrode to the first section; and an electrically insulating layer between the LED die, the electrically conductive layer, and the transparent electrically conducting layer, wherein the electrically insulating layer insulates the transparent ele

Abstract: A light emitting diode (LED) includes a substrate and an eputaxial layer on the substrate. The epitaxial layer includes a N-type GaN-based layer, a light emitting layer, and a P-type GaN-based layer. The LED further includes a first electrode on the N-type GaN-based layer and a second electrode on the P-type GaN-based layer. The P-type GaN-based layer has a inactive portion, and the second electrode is located and covers the inactive portion.

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: A light emitting diode includes a substrate, a transitional layer on the substrate and an epitaxial layer on the transitional layer. The transitional layer includes a planar area with a flat top surface and a patterned area with a rugged top surface. An AlN material includes a first part consisting of a plurality of spheres and a second part consisting of a plurality of slugs. The spheres are on a top surface of the transitional layer, both at the planar area and the patterned area. The slugs are in grooves defined in the patterned area. Air gaps are formed between the slugs and a bottom surface of the epitaxial layer. The spheres and slugs of the AlN material help reflection of light generated by the epitaxial layer to a light output surface of the LED.

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.