A light-emitting device having four or more LEDs arranged on a substrate includes a first color conversion layer and a second color conversion layer. The first color conversion layer is continuously formed on light exit surfaces of two or more of the LEDs, and the second color conversion layer is continuously formed on light exit surfaces of two or more of the LEDs that are different from the LEDs on which the first color conversion layer is formed.

A light-emitting device having four or more LEDs arranged on a substrate includes a first color conversion layer and a second color conversion layer. The first color conversion layer is continuously formed on light exit surfaces of two or more of the LEDs, and the second color conversion layer is continuously formed on light exit surfaces of two or more of the LEDs that are different from the LEDs on which the first color conversion layer is formed.

A method of manufacturing a patterned substrate includes: providing an exposure mask that includes: a plurality of inner light-shielding portions arranged in a lattice, a light-transmissive portion integrally connecting regions surrounding the plurality of inner light-shielding portions, and an outer light-shielding portion surrounding the light-transmissive portion; performing a plurality of exposures of a photoresist layer disposed on a substrate in a step-and-repeat-manner using the exposure mask, so as to form a plurality of inner projected parts corresponding to the inner light-shielding portions, the inner projected parts being aligned in a lattice as a whole; developing the photoresist layer on which the plurality of exposures have been performed; and etching the substrate using the developed photoresist layer as a mask.

A method of manufacturing a patterned substrate includes: providing an exposure mask that includes: a plurality of inner light-shielding portions arranged in a lattice, a light-transmissive portion integrally connecting regions surrounding the plurality of inner light-shielding portions, and an outer light-shielding portion surrounding the light-transmissive portion; performing a plurality of exposures of a photoresist layer disposed on a substrate in a step-and-repeat-manner using the exposure mask, so as to form a plurality of inner projected parts corresponding to the inner light-shielding portions, the inner projected parts being aligned in a lattice as a whole; developing the photoresist layer on which the plurality of exposures have been performed; and etching the substrate using the developed photoresist layer as a mask.

A light emitting diode having multiple tunnel junctions is provided. This comprises the common contact layer, the first and second tunnel junction layers respectively disposed on the bottom surface and the upper surface of the common contact layer, the first light emitting structure disposed on the bottom surface of the first tunnel junction layer and the second light emitting structure disposed on the upper surface of the second tunnel junction layer. Light emitting structures emitting blue and green light may be disposed above and below the common contact layer. By injecting holes into the first light emitting structure and the second light emitting structure through the common contact layer formed of the n-type semiconductor, current spreading effect is improved, leading to improved light emitting efficiency. Since the n-type semiconductor layer can be disposed on the upper surface exposed to the outside, risk of damage occurring in subsequent fabrication steps can be reduced.

The present disclosure provides a light-emitting device comprising a substrate with a topmost surface; a first semiconductor stack arranged on the substrate, and comprising a first top surface separated from the topmost surface by a first distance; a first bonding layer arranged between the substrate and the first semiconductor stack; a second semiconductor stack arranged on the substrate, and comprising a second top surface separated from the topmost surface by a second distance which is different form the first distance; a second bonding layer arranged between the substrate and the second semiconductor stack; a third semiconductor stack arranged on the substrate, and comprising third top surface separated from the topmost surface by a third distance; and a third bonding layer arranged between the substrate and the third semiconductor stack; wherein the first semiconductor stack, the second semiconductor stack, and the third semiconductor stack are configured to emit different color lights.

A method of manufacturing a light emitting device includes: bonding a plurality of light emitting elements each having an outer peripheral lateral surface onto a light-transmissive substrate; forming at least one groove on the light-transmissive substrate to surround an outer periphery of each of the plurality of light emitting elements; disposing at least one light guiding member in the groove to continuously cover the groove and the outer peripheral lateral surfaces of adjacent ones of the plurality of light emitting elements; and singulating the light-transmissive substrate at a position between adjacent ones of the plurality of light emitting elements, to obtain a plurality of light emitting devices in each of which at least one of the light emitting elements is bonded to a single light-transmissive member.

A method of manufacturing a light emitting device includes: bonding a plurality of light emitting elements each having an outer peripheral lateral surface onto a light-transmissive substrate; forming at least one groove on the light-transmissive substrate to surround an outer periphery of each of the plurality of light emitting elements; disposing at least one light guiding member in the groove to continuously cover the groove and the outer peripheral lateral surfaces of adjacent ones of the plurality of light emitting elements; and singulating the light-transmissive substrate at a position between adjacent ones of the plurality of light emitting elements, to obtain a plurality of light emitting devices in each of which at least one of the light emitting elements is bonded to a single light-transmissive member.

A light-emitting audio device, an audio output device, and a display device. The light-emitting audio device includes a micro device integrated with a micro LED device and piezoelectric device. Both image display and audio output can be enabled using a single device. Audio is output using a plurality of light-emitting audio devices disposed in a plurality of subpixels, respectively. An increase in the thickness of the display device due to integrate with a audio function can be minimized. A variety of audio output functions are provided by driving the light-emitting audio devices according to areas.

A light-emitting audio device, an audio output device, and a display device. The light-emitting audio device includes a micro device integrated with a micro LED device and piezoelectric device. Both image display and audio output can be enabled using a single device. Audio is output using a plurality of light-emitting audio devices disposed in a plurality of subpixels, respectively. An increase in the thickness of the display device due to integrate with a audio function can be minimized. A variety of audio output functions are provided by driving the light-emitting audio devices according to areas.