A lower sheet disposed below a display panel includes a heat radiation layer having a first side and a second side facing the first side. A first film layer is disposed on the first side of the heat radiation layer. A second film layer is disposed on the second side of the heat radiation layer. A first resin layer is disposed between the heat radiation layer and the first film layer. A second resin layer is disposed between the heat radiation layer and the second film layer. A sealing layer is disposed on lateral sides of the heat radiation layer. The sealing layer directly contacts an entirety of the lateral sides of the heat radiation layer, and directly contacts at least a portion of lateral sides of the first resin layer and the second resin layer.

A method includes providing a ceramic substrate having a first arrangement portion recessed from a first planar portion; disposing a first conductive paste containing a first metal powder in the first arrangement portion; obtaining a first conductor by firing the first conductive paste; forming first recessed portions on a surface of the first conductor disposed in the first arrangement portion by polishing the first conductor and the ceramic substrate so that the first conductor and the first surface form a same plane; disposing a second conductive paste containing a second metal powder and a second organic resin binder in the first recessed portions; obtaining a second conductor by curing the second conductive paste; polishing the second conductor so that the second conductor and the first conductor form the same plane; and forming a first metal layer on surfaces of the first conductor and the second conductor.

A light emitting device includes: a resin package including: a resin part, and a plurality of leads including a first lead and a second lead, wherein the resin package has a concave portion having a bottom face at which a part of an upper surface of the first lead and a part of an upper surface of the second lead are exposed from the resin part; a light emitting element mounted on the bottom face of the concave portion; and a sealing member covering the light emitting element in the concave portion. The plurality of leads comprise a plurality of notch parts including a first notch part on a first side corresponding to a first outer side surface of the resin package and a second notch part on a second side corresponding to a second outer side surface of the resin package.

A ceramic insulating film (150) having a heat conducting property and a light reflecting property is formed on a front surface of a substrate (100), and a light emitting element (110) is provided on the ceramic insulating film. This makes it possible to improve a heat dissipation characteristic and a light utilization efficiency of a light emitting apparatus (10) having the light emitting element (101) provided on the substrate (110).

To provide an LED lighting apparatus and a method for manufacturing the same that can improve the bonding strength between an aluminum substrate and a printed wiring substrate. An LED lighting apparatus and a method for manufacturing the same, the LED lighting apparatus includes an aluminum substrate, a plurality of reflectivity-enhanced layers formed on the aluminum substrate, an LED device bonded on said plurality of reflectivity-enhanced layers, a printed wiring substrate bonded onto a region on the aluminum substrate other than a region where the plurality of reflectivity-enhanced layers are formed, a wire for connecting between the printed wiring substrate and the LED device, a frame member formed so as to surround said LED device, and a phosphor resin deposited over a region inside the frame member.

A light-emitting apparatus package of the present invention includes (i) an electrically insulated ceramic substrate, (ii) a first concave section formed in the direction of thickness of the ceramic substrate so as to form a light exit aperture in a surface of the ceramic substrate, (iii) a second concave section formed within the first concave section in the further direction of thickness of the ceramic substrate so that one or more light-emitting devices are provided therein, (iv) a wiring pattern for supplying electricity, which is provided in the first concave section, and (v) a metalized layer having light-reflectivity, which is (a) provided between the light-emitting device and the surface of the second concave section of the substrate, and (b) electrically insulated from the wiring pattern. On the account of this, the light-emitting apparatus package in which heat is excellently discharged and light is efficiently utilized and a light-emitting apparatus in which the light-emitting apparatus package is used can be obtained.

A light emitting device includes a metal support structure comprising Cu; an adhesion structure on the metal support structure and comprising Au; a reflective conductive contact on the adhesion structure; a GaN-based semiconductor structure on the reflective conductive contact, the GaN-based semiconductor structure comprising a first-type GaN layer, an active layer, and a second-type GaN layer; a top interface layer on the GaN-based semiconductor structure and comprising Ti; and a contact pad on the top interface layer and comprising Au, wherein the GaN-based semiconductor structure is less than 1/20 thick of a thickness of the metal support structure.

A light emitting device package including a package body including a first cavity and a second cavity, a pad disposed on a bottom surface of the first cavity, a light emitting device disposed on the second cavity electrically connected to the pad, a heat dissipation member inserted into the package body, the heat dissipation member including a body and expanded portions disposed at a partial edge region of the body and electrode patterns disposed at the package body, wherein the package body has an upper portion and a lower portion disposed under the upper portion, wherein the first cavity including side surfaces and a bottom surface, wherein the second cavity provided in the bottom surface of the first cavity.

There is provided an electronic component mounting substrate which excels in resistance to migration, and is thus capable of maintaining high thermal conductivity and insulation performance for a long period of time. An electronic component mounting substrate includes: a metallic substrate formed of aluminum or an aluminum-based alloy; an alumite layer disposed on the metallic substrate, having a network of crevices at an upper surface thereof; and a ceramic layer disposed on the alumite layer, part of the ceramic layer extending into the crevices.

By using a light emitting device including an insulating substrate and a light emitting unit formed on the insulating substrate, the light emitting unit including: a plurality of linear wiring patterns disposed on the insulating substrate in parallel with one another, a plurality of light emitting elements that are mounted between the wiring patterns while being electrically connected to the wiring patterns, and a sealing member for sealing the light emitting elements, as well as a method for manufacturing thereof, it becomes possible to provide a light emitting device that achieves sufficient electrical insulation and has simple manufacturing processes so that it can be manufactured at a low cost, and a method for manufacturing the same.