A carrier leadframe, including a frame body and a carrier, is provided. The frame body includes at least one supporting portion, and the carrier includes a shell and at least one electrode portion and is mechanically engaged with the frame body via the supporting portion. A method for manufacturing the carrier leadframe as described above, as well as a light emitting device made from the carrier leadframe and a method for manufacturing the device, are also provided. The carrier leadframe has carriers that are separate in advance and mechanically engaged with the frame body, thereby facilitating the quick release of material after encapsulation. Besides, in the carrier leadframe as provided, each carrier is electrically isolated from another carrier, so the electric measurement can be performed before the release of material. Therefore, the speed and yield of production of the light emitting device made from the carrier leadframe is improved.

Submount based light emitter components and related methods are disclosed. In some aspects, light emitter components include a ceramic submount, at least a first pair of electrical traces disposed on a first side of the submount, at least a first pair of electrical contacts disposed on a second side of the submount, at least one light emitter chip disposed on the first side of the submount, and a non-ceramic reflector disposed about the at least one light emitter chip. The first pair of electrical contacts is configured to electrical communicate with the first pair of electrical traces. The at least one chip is configured to electrically communicate with the first pair of electrical traces. At least a portion of the reflector is configured to conceal a portion of each trace of the first pair of electrical traces.

Provided is a method that can manufacture a light-emitting device in which quantum dot is used and which has a high luminous efficiency. A light-emitting device (1) is manufactured that includes: a cell (10) including first and second glass plates (11, 12) facing and spaced apart from each other; and quantum dot (17) encapsulated in the cell (10). Prior to the encapsulation of the quantum dot (17), a reduction step of reducing moisture adsorbed on the inside walls of the cell (10) is performed.

A packaged light emitting device die includes a package body having a profiled leadframe embedded in a body of reflecting material. The leadframe is exposed on mounting surface only on at least one solder bonding area. Solder is present only on the at least one solder bonding area and not elsewhere. The reflecting material provides the reflecting parts of the package so there is no need for a reflective layer to be deposited on leadframe. Moreover, the reflecting material can function as a solder resist to self-align the solder to the at least one solder bonding area.

An LED carrier includes a substrate, a metallic layer, an insulating layer, and a reflecting layer. The metallic layer is disposed on the substrate and has a die bonding region and a ring-shaped wiring region separated from the die bonding region. A region arranged between the die bonding region and the ring-shaped wiring region is defined as an insulating region. The insulating layer at least partially covers the insulating region. The reflecting layer is arranged above the die bonding region and at least partially covers the top surface of the insulating layer. Moreover, the instant disclosure also provides a manufacturing method of an LED carrier.

A light emitting device is provide comprising a light emitting diode (LED) chip having a first main surface and a second main surface opposing the first main surface, and one or more side surfaces extending between the first main surface and second main surface. A plurality of electrodes is disposed on the first main surface. A wavelength conversion film is disposed on the second main surface. A mark is formed in the wavelength conversion film. The mark contains orientation information of the light emitting device, thereby enabling the light emitting device to be properly oriented on a receiving substrate.

A method for manufacturing a light emitting device is provided. Multiple epitaxial structures and multiple bonding pads formed thereon are formed on a growth substrate. A first adhesive layer is formed on the growth substrate, wherein the first adhesive layer encapsulates the epitaxial structures and the bonding pads. A first substrate is provided on the first adhesive layer. The growth substrate is removed, so as to expose the epitaxial structures and the first adhesive layer. A second substrate and a second adhesive layer disposed thereon are provided, wherein the epitaxial structures are adhered on the second substrate by the second adhesive layer. The first adhesive layer and the first substrate are removed.

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.

Flexible LED assemblies that have coplanar integrated conductive features upon which an LED can be mounted, and methods of making such LED assemblies are described. The flexible LED assembly includes a flexible polymer substrate, a first conductive feature, a second conductive feature and an LED. The first conductive feature is positioned both within the flexible substrate and on a surface of the flexible substrate. The second conductive feature is positioned both within the flexible substrate and on a surface of the flexible substrate. The first and second conductive features are separated by a gap therebetween. The LED is mounted on both the first and second conductive features, and the first and second conductive features are substantially coplanar with one another.

A package includes a plurality of electrode pairs, each electrode pair including a first electrode on one side and a second electrode on another side in a plan view. The first electrode is electrically connected to the second electrode included in an electrode pair adjacent to a first or second lateral side of the one electrode pair, and is not electrically connected to the first electrode included in the electrode pair adjacent to the first or second side of the one electrode pair. The second electrode is electrically connected to the first electrode included in an electrode pair adjacent to a lower side of the one electrode pair, and is not electrically connected to the second electrode included in the electrode pair adjacent to the first or second lateral side of the one electrode pair.