Abstract: Disclosed is a micro light-emitting component, a micro light-emitting diode, and a transfer layer. The transfer layer has a recess for receiving the micro light-emitting diode to permit the micro light-emitting diode to be retained by the transfer layer, and is transformable from a first state, in which the transfer layer is deformed by the micro light-emitting diode to form the recess, to a second state, in which the micro light-emitting diode received in the recess is retained by the transfer layer. Also disclosed are micro light-emitting component matrix and a method for manufacturing the micro light-emitting component matrix.

Abstract: A flip-chip LED device includes an epitaxial structure, a first contact electrode, and a second contact electrode. The second contact electrode is disposed on the epitaxial structure and extending toward the first contact electrode. The second contact electrode includes a first curved extension, a second curved extension, a connecting portion, a first straight extension, and a second straight extension. The connecting portion is connected to the first curved extension and to the second curved extension. The first straight extension is connected to the first curved extension. The second straight extension is connected to the second curved extension.

Abstract: A semiconductor light emitting device includes a multi-quantum-well structure, a first capping layer, a second capping layer, and an electron barrier layer stacked in order. The multi-quantum-well structure includes a plurality of alternately-stacked potential barrier layers and potential well layers. The first capping layer is a semiconductor layer, and the second capping layer is a p-doped semiconductor layer. Each of the first and second capping layers has an aluminum mole fraction larger than that of each of the potential barrier layers, and the aluminum mole fraction of the first capping layer is larger than that of at least a portion of the electron barrier layer. A method for preparing the semiconductor light emitting device is also provided.

Abstract: An epitaxial light emitting structure includes n-type and p-type semiconductor layers, and a light emitting component disposed therebetween. The light emitting component includes a multiple quantum well structure which contains a plurality of first periodic layered elements, each of which includes first, second and third layers alternately stacked on one another. For each of the first periodic layered elements, the first, second and third layers respectively have a first energy bandgap (Eg1), a second energy bandgap (Eg2), and a third energy bandgap (Eg3) that satisfy a relationship of Eg1<Eg2<Eg3. Also disclosed herein is a light emitting diode which includes the aforementioned epitaxial light emitting structure.

Abstract: A nitride-based light-emitting diode (LED) device includes an n-type nitride semiconductor layer, an active layer that is disposed on the n-type nitride semiconductor layer, a p-type nitride semiconductor layer disposed on the active layer, and a defect control unit disposed between the n-type nitride semiconductor layer and the active layer. The defect control unit includes first, second and third defect control layers that are sequentially disposed on the n-type nitride semiconductor layer in such order, and that have different doping concentrations. The third defect control layer includes one of Al-containing ternary nitride, Al-containing quaternary nitride, and a combination thereof.

Abstract: A light-emitting apparatus includes an LED element substrate containing a wiring pattern provided on a surface side of the substrate, at least one light-emitting device mounted on amounting area of the substrate and electrically connecting to the wiring pattern, a connecting substrate provided on the LED element substrate, and a transparent member provided over a top surface of the light-emitting device. The connecting substrate has a light-transmitting section provided in a position corresponding to a position of the light-emitting device to suppress the broadening of light emitted from the light-emitting device. The light-transmitting section causes the light from the light-emitting device to pass through or to transmit.

Abstract: A semiconductor device includes a semiconductor layered structure, an electrode unit, and an anti-adsorption layer. The electrode unit is disposed on an electrode connecting region of the semiconductor layered structure. The anti-adsorption layer is disposed on a top surface of the electrode unit opposite to the semiconductor layered structure and is electrically connected to the electrode unit. The anti-adsorption layer has an adsorption capacity for at least one of gaseous contaminants and particulate contaminants which is lower than that of the electrode unit. Also disclosed herein is a light-emitting system including the semiconductor device.

Abstract: A micro light-emitting device includes a support structure with a cavity and at least one micro light-emitting element that includes a semiconductor structure accommodated by the cavity, at least one bridge connection member disposed on the semiconductor structure to interconnect the semiconductor structure and the support structure, and a protruding contact member disposed on at least one of the semiconductor structure and the bridge connection member and protruding therefrom to be configured to contact with a transfer means. The device is configured to contact with the transfer means at the protruding contact member of the element. A transfer method using the device is also disclosed.

Abstract: A light-emitting package includes a substrate having a mounting area, one or more light-emitting devices mounted on the mounting area of the substrate, a transparent resin section having a light transmitting property for sealing the one or more light-emitting devices, and a light-reflective member molded on one part of the substrate, which is outside the mounting area on which the one or more light-emitting devices are mounted. There is a distance greater than zero between the light-reflective member and the mounting area.

Abstract: A micro light-emitting diode (LED) includes an epitaxial layered structure including a support layer, a first-type semiconductor element, an active layer, and a second-type semiconductor element that are sequentially disposed on one another in such order. A method for manufacturing a micro LED device including at least one of the micro LED is also disclosed.

Abstract: A light emitting device includes a light emitting structure, first and second electrodes, and a shielding layer. The light emitting structure includes a first-type semiconductor layer, an active layer, and a second-type semiconductor layer that are stacked along a stacking direction in such order. The first electrode is electrically connected to the first-type semiconductor layer. The second electrode is electrically connected to the second-type semiconductor layer. The shielding layer is connected to aside of the light emitting structure and is adapted to absorb or reflect incident laser light.

Abstract: A light-emitting device includes a substrate, multiple light-emitting units that are disposed on the substrate, that are spaced apart by an isolation trench and that are and electrically interconnected by an interconnecting structure, and an insulating layer with thickness of 200 nm to 450 nm. A potential difference between adjacent two light-emitting units not in direct electrical connection is at least two times forward voltage of each of the light-emitting units. Each light-emitting unit includes a light-emitting stack and a light-transmissible current spreading layer. The insulating layer covers the light-transmissible current spreading layers and at least a part of the light-emitting stacks.

Abstract: A light-emitting diode includes an N-type cladding layer, and a superlattice structure, an active layer, a P-type electron-blocking layer, and a P-type cladding layer disposed on the N-type cladding layer in such order. The superlattice structure includes at least one first layered element which has first, second, and third sub-layers that are stacked on one another in a direction away from the N-type cladding layer. The first, second, and third sub-layers have energy band gaps Eg1, Eg2, and Eg3 which satisfy a relationship of Eg1<Eg2<Eg3. In addition, Eg3 is greater than an energy band gap of the P-type electron-blocking layer.

Abstract: A light-emitting device includes: a light-emitting mesa structure having a first top surface and a peripheral surface connected to the first top surface; a transparent conductive layer that is disposed on the first top surface and that has a second top surface; a first insulating structure that is at least disposed on the peripheral surface and that has a third top surface and an inner tapered surface indented from the third top surface, the inner tapered surface having an acute angle with respect to the second top surface; and a reflective layer that is disposed on the transparent conductive layer and that has a first side surface in contact with the inner tapered surface. A method for manufacturing the light-emitting device is also disclosed.

Abstract: A laser diode includes a light-emitting stack, and a distributed Bragg reflection (DBR) cover layer in contact with the light-emitting stack. The light-emitting stack includes an N-type layer, an active layer, and a P-type layer that has a ridged member. The ridged member has an end face including a first inclined surface that inclines with respect to a top surface of the ridged member in an outward and downward direction from the top surface. A contact interface between the ridged member and the DBR cover layer includes the first inclined surface. A method for making the laser diode is also disclosed.

Abstract: Disclosed is a multi-quantum well structure including a stress relief layer, an electron-collecting layer disposed on the stress relief layer, and an active layer including a first active layer unit that is disposed on the electron-collecting layer. The first active layer unit includes potential barrier sub-layers and potential well sub-layers being alternately stacked, in which at least one of the potential barrier sub-layers has a GaN/Alx1Iny1Ga(1-x1-y1)N/GaN stack, where 0<x1?1 and 0?y1<1, and for the remainder of the potential barrier sub-layers, each of the potential barrier sub-layers is a GaN layer. An LED device including the multi-quantum well structure is also disclosed.

Abstract: A transfer system for transferring multiple microelements to a receiving substrate includes a main pick-up device, a testing device, and first and second carrier plates. The testing device includes a testing platform, a testing circuit, and multiple testing electrodes electrically connected to the testing circuit. The main pick-up device is operable to releasably pick up the microelements from the first carrier plate and position the microelements on the testing electrodes. The testing device is operable to test the microelements to distinguish unqualified ones of the microelements from qualified ones. The main pick-up device is operable to release the qualified ones of the microelements to the receiving substrate.

Abstract: Disclosed herein is a light emitting diode (LED), which includes a first-type semiconductor unit, an active layer formed on the first-type semiconductor unit, and a second-type semiconductor unit formed on the active layer oppositely of the first-type semiconductor unit. The second-type semiconductor unit includes a hole storage structure that has a polarization field having a direction pointing toward the active layer.

Abstract: A focus-adjustable lighting device includes a housing, a light source module, a focus-adjustable mechanism, and a light guiding unit. The focus-adjustable mechanism includes a rotating member and a first limiting member. The rotating member is rotatable relative to the housing, and has a semi-helical guide groove, and an engaging unit that includes a plurality of spaced-apart concave grooves corresponding in position to the semi-helical guide groove. The first limiting member includes a first limiting portion disposed in the semi-helical guide groove, and a second limiting portion spaced apart from the first limiting portion. The light guiding unit is movable with the rotating member.

Abstract: A method of manufacturing a flip-chip light emitting diode includes: providing a transparent substrate and a temporary substrate, and bonding the transparent substrate with the temporary substrate; grinding and thinning the transparent substrate; providing a light-emitting epitaxial laminated layer having a first surface and a second surface opposite to each other, and including a first semiconductor layer, an active layer and a second semiconductor layer; forming a transparent bonding medium layer over the first surface of the light-emitting epitaxial laminated layer, and bonding the transparent bonding medium layer with the transparent substrate; defining a first electrode region and a second electrode region over the second surface of the light-emitting epitaxial laminated layer, and manufacturing a first electrode and a second electrode; and removing the temporary substrate.