A method for manufacturing a light-emitting device of the present invention includes a step in which solid-state sealing resin (17) containing a phosphor (18) and the solid-state sealing resin (17) containing a phosphor (19) are arranged in recesses in package resin (14) having LED chips placed thereon, are thereafter melted by heating, and, in addition, are cured by heating.

The present disclosure provides a method for manufacturing a light-emitting device, comprising: providing a first substrate; providing a semiconductor stack on the first substrate, the semiconductor stack comprising a first conductive type semiconductor layer, a light-emitting layer on the first conductive type semiconductor layer, and a second conductive type semiconductor layer on the light-emitting layer, wherein the semiconductor stack is patterned and comprises a plurality of blocks of semiconductor stack separated from each other, and wherein the plurality of blocks of semiconductor stack comprise a first block of semiconductor stack and a second block of semiconductor stack; performing a separating step to separate the first block of semiconductor stack from the first substrate, and the second block of semiconductor stack remained on the first substrate; providing a permanent substrate comprising a first surface, a second surface, and a third block of semiconductor stack on the first surface; and bonding one of the first block of semiconductor stack and the second block of semiconductor stack to the second surface.

Provided is a light emitting device with improved light extracting efficiency and further higher heat releasing performance. A light emitting device includes a planar lead frame having a first lead and a second lead, and includes a light emitting element mounted on the first lead, a resin frame surrounding a periphery of the light emitting element, a first sealing resin filled in the inner side of the resin frame and sealing the light emitting element, and a second sealing resin covering the resin frame and the first sealing resin. Lower end of inner surface of the resin frame is arranged only on the first lead, and at an outside of the resin frame, and the second resin member covers at least a part of the first lead and the second lead. Of the back-surface of the first lead, a region directly under the blight emitting element is exposed.

A Chip-Scale Packaging (CSP) LED device and a method of manufacturing the same are disclosed. The CSP LED device includes a flip-chip LED semiconductor die and a packaging structure, wherein the packaging structure comprises a soft buffer layer, a photoluminescent structure and an encapsulant structure. The soft buffer layer includes a top portion formed on top of the flip-chip LED semiconductor die, and an edge portion formed covering an edge surface of the flip-chip LED semiconductor die, wherein the top portion has a convex surface, and the edge portion has an extension surface smoothly adjoining the convex surface. The photoluminescent structure is formed on the soft buffer layer covering the convex surface and the extension surface of the soft buffer layer. The encapsulant structure, which has a hardness not lower than that of the buffer layer, is formed on the photoluminescent structure. Therefore, the CSP LED device has improved reliability by improving adhesion strength between the flip-chip LED semiconductor die and the packaging structure, and improved optical performance such as more consistent correlated color temperature (CCT), more uniform spatial color, and higher optical efficacy.

A hollow frame is configured to surround the periphery of a substantially self-supporting flip-chip light emitting device. The frame may be shaped to also contain a wavelength conversion element above the light emitting surface of the light emitting device. The lower surface of the light emitting device, which is exposed through the hollow frame, includes contact pads coupled to the light emitting element for surface mounting the light emitting module on a printed circuit board or other fixture. The flip-chip light emitting device may include a patterned sapphire substrate (PSS) upon which the light emitting element is grown, the patterned surface providing enhanced light extraction from the light emitting element, through the patterned sapphire substrate.

A method of manufacturing a multichip package structure includes providing a substrate body; placing a plurality of light-emitting chips on the substrate body, the light-emitting chips being electrically connected to the substrate body; surroundingly forming surrounding liquid colloid on the substrate body to surround the light-emitting chips; naturally drying an outer layer of the surrounding liquid colloid at a predetermined room temperature to form a semidrying surrounding light-reflecting frame, the semidrying surrounding light-reflecting frame having a non-drying surrounding colloid body disposed on the substrate body and a dried surrounding colloid body totally covering the non-drying surrounding colloid body; and then forming a package colloid body on the substrate body to cover the light-emitting chips, the semidrying surrounding light-reflecting frame contacting and surrounding the package colloid body.

An optoelectronic semiconductor component including an optoelectronic semiconductor chip having a first surface, wherein the first surface is a radiation emission surface of the optoelectronic semiconductor chip, the semiconductor chip is embedded in a mold body, the first surface is elevated with respect to a top side of the mold body, and a reflective layer is arranged on the top side of the mold body.

A light emitting device includes a base member, a light emitting element, and a sealing member. The substrate includes a wiring portion. The element is arranged on or above the substrate. The sealing member covers the element, and at least a part of the substrate. The sealing member includes a wavelength conversion member. The part of the substrate is divided into first and second sections by a straight line that passes through the center of the part as viewed in plan view. The wiring portion is arranged so that its area on the first section side is larger than on the second section side. The element is arranged so that its area in the second section is larger than the first section. The height of the sealing member on the second section side is greater than on the first section side.

A method is specified for producing an optoelectronic semiconductor component, comprising the following steps: A) providing a structured semiconductor layer sequence (21, 22, 23) having a first semiconductor layer (21) with a base region (21c), at least one well (211), and a first cover region (21a) in the region of the well (211) facing away from the base surface (21c), an active layer (23), and a second semiconductor layer (22) on a side of the active layer (23) facing away from the first semiconductor layer (21), wherein the active layer (23) and the second semiconductor layer (22) are structured jointly in a plurality of regions (221, 231) and each region (221, 231) forms, together with the first semiconductor layer (21), an emission region (3), B) simultaneous application of a first contact layer (41) on the first cover surface (21a) and a second contact layer (42) on a second cover surface (3a) of the emission regions (3) facing away from the first semiconductor layer (21) in such a way that the first contact layer (41) and the second contact layer (42) are electrically separated from each other, and the first contact layer (41) and the second contact layer (42) run parallel to each other.

A method of manufacturing a plurality of light emitting devices includes providing a collective substrate including a plurality of packages, each of the packages including: a recess defined by lateral surfaces and a bottom surface, a first electrode and a second electrode that are disposed at the bottom surface of the recess, and a light-reflective first resin member surrounding an element-mounting region of the bottom surface of the recess, the first resin member having an upper surface located at a position higher than the element-mounting region; mounting a light emitting element in the element-mounting region; forming a light-reflective second resin member having a light reflective surface; and singulating the collective substrate to obtain the plurality of light emitting devices.