A light emitting device that is inexpensive, is easy to manufacture, and has high light extraction efficiency is provided. The light emitting device includes an oriented polycrystalline substrate, a plurality of columnar light emitting parts, and a light confinement layer. The oriented polycrystalline substrate includes a plurality of oriented crystal grains. The plurality of columnar light emitting parts are discretely located on or above one main surface of the oriented polycrystalline substrate in areas in which there are no crystal defects, and are each a columnar part having a longitudinal direction matching a normal direction of the oriented polycrystalline substrate. The light confinement layer is made of a material having a lower refractive index than a material for the plurality of columnar light emitting parts, and is located on or above the oriented polycrystalline substrate so as to surround the plurality of columnar light emitting parts.

A flip-chip light emitting device includes: a light-emitting epitaxial laminated layer with two opposite surfaces, in which, the first surface is a light-emitting surface; a first electrode and a second electrode that are separated from each other on the second surface of the light-emitting epitaxial laminated layer; a non-conductive substrate with two opposite surfaces and two side walls connecting those two surfaces, in which, the first surface is connected to the light-emitting epitaxial laminated layer through the first and the second electrodes; a first external electrode and a second external electrode on the second surface of the non-conductive substrate, which extend to the side walls of the non-conductive substrate till and at least cover parts of the side walls of the first and the second electrodes to form electrical connection.

Embodiments of the invention include a plurality of light emitting devices (1), one of the light emitting devices in the plurality being configured to emit light having a first peak wavelength. A wavelength converting layer (30) is disposed in a path of light emitted by the plurality of light emitting devices. The wavelength converting layer (30) absorbs light emitted by the light emitting device and emits light having a second peak wavelength. The light emitting devices (1) are mechanically connected to each other only through the wavelength converting layer (30). In other embodiments a light converting layer is placed over the light emitting devices and an adhesive or optical element layer is placed at the side surfaces and over the light converting layer, the light emitting devices are mechanically connected to each other only through the wavelength converting layer.

Fluidic assembly methods are presented for the fabrication of emissive displays. An emissive substrate is provided with a top surface, and a first plurality of wells formed in the top surface. Each well has a bottom surface with a first electrical interface. Also provided is a liquid suspension of emissive elements. The suspension is flowed across the emissive substrate and the emissive elements are captured in the wells. As a result of annealing the emissive substrate, electrical connections are made between each emissive element to the first electrical interface of a corresponding well. A eutectic solder interface metal on either the substrate or the emissive element is desirable as well as the use of a fluxing agent prior to thermal anneal. The emissive element may be a surface mount light emitting diode (SMLED) with two electrical contacts on its top surface (adjacent to the bottom surfaces of the wells).

A method of depositing an unpackaged semiconductor die (die) onto a substrate. The method includes writing a latent image on a photosensitive drum. The latent image represents an outline for the die to be placed onto the substrate. The photosensitive drum is configured to have an electro-static charge and the die is transferred from the developing unit to the photosensitive drum so as to deposit the die onto the substrate according to the outline.

A protective covering configured for use with a mobile electronics device, including a front wall and a plurality of side walls defining a primary cavity. A back wall is disposed within the primary cavity separating the primary cavity into a protective covering electronics housing cavity and a mobile electronic device housing cavity. One or more apertures are disposed within the front wall. A light source is disposed within the protective covering electronics housing cavity, wherein at least a portion of the light source is disposed outside of the protective covering electronics housing cavity and through at least one of the one or more apertures in the front wall. A heat sink is disposed within the protective covering electronics housing cavity and in contact with the light source.

Solid-state radiation transducer (SSRT) devices and methods of manufacturing and using SSRT devices are disclosed herein. One embodiment of the SSRT device includes a radiation transducer (e.g., a light-emitting diode) and a transmissive support assembly including a transmissive support member, such as a transmissive support member including a converter material. A lead can be positioned at a back side of the transmissive support member. The radiation transducer can be flip-chip mounted to the transmissive support assembly. For example, a solder connection can be present between a contact of the radiation transducer and the lead of the transmissive support assembly.

In accordance with certain embodiments, semiconductor dies are at least partially coated with a conductive adhesive prior to singulation and subsequently bonded to a substrate having electrical traces thereon.

In one embodiment, the disclosure relates to a system of stacked and connected layers of circuits that includes at least one pair of adjacent layers having very few physical (electrical) connections. The system includes multiple logical connections. The logical interconnections may be made with light transmission. A majority of physical connections may provide power. The physical interconnections may be sparse, periodic and regular. The exemplary system may include physical space (or gap) between the a pair of adjacent layers having few physical connections. The space may be generally set by the sizes of the connections. A constant flow of coolant (gaseous or liquid) may be maintained between the adjacent pair of layers in the space.

A light emitting device mount includes a positive lead terminal, and a negative lead terminal. Each of the positive and negative lead terminal includes a first main surface, a second main surface, and an end surface. The end surface is provided between the first main surface and the second main surface. The end surface includes a first recessed surface area and a second recessed surface area. The first recessed surface area is extending from a first point of the first main surface in cross section. The second recessed surface area is extending from a second point of the second main surface in cross section. The first and second recessed surface areas define a protruding portion protruding outwardly.