Disclosed are a light emitting device, a method of fabricating the same, a light emitting device package, and a lighting system. The light emitting device may include a substrate, a first conductive semiconductor layer on the substrate, an active layer on the first conductive semiconductor layer, a second conductive semiconductor layer on the active layer, an ohmic layer on the second conductive semiconductor layer, an insulating layer on the ohmic layer, a first branch electrode electrically connected with the first conductive semiconductor layer, a first pad electrode connected with the first branch electrode for electrical connection with the first conductive semiconductor layer, a second pad electrode in contact with the ohmic layer through the insulating layer, a second branch electrode connected with the second pad electrode on the insulating layer, and a second through electrode passing through the insulating layer to connect the second branch electrode with the ohmic layer.

The light emitting element is provided to comprise: a first conductive type semiconductor layer; a mesa; a current blocking layer; a transparent electrode; a first electrode pad and a first electrode extension; a second electrode pad and a second electrode extension; and an insulation layer partially located on the lower portion of the first electrode, wherein the mesa includes at least one groove formed on a side thereof, the first conductive type semiconductor layer is partially exposed through the groove, the insulation layer includes an opening through which the exposed first conductive type semiconductor layer is at least partially exposed, the first electrode extension includes extension contact portions in contact with the first conductive type semiconductor layer through an opening, and the second electrode extension includes an end with a width different from the average width of the second electrode extension.

Aspects include Light Emitting Diodes that have a GaN-based light emitting region and a metallic electrode. The metallic electrode can be physically separated from the GaN-based light emitted region by a layer of porous dielectric, which provides a reflecting region between at least a portion of the metallic electrode and the GaN-based light emitting region.

In various embodiments, light-emitting devices incorporate smooth contact layers and polarization doping (i.e., underlying layers substantially free of dopant impurities) and exhibit high photon extraction efficiencies.

A light emitting device includes a light emitting structure having a plurality of light emitting regions including a first semiconductor layer, an active layer, a second semiconductor layer, a first electrode in one of the light emitting regions, a second electrode in another of the light emitting regions, and at least one connection electrode to sequentially connect the light emitting regions in series. The light emitting regions connected in series are divided into 1st to ith light emitting region groups. Areas of light emitting regions that belong to different groups are different. An area of a light emitting region which is more frequently used among the plurality of light emitting regions is larger than an area of a light emitting region which is less frequently used among the plurality of light emitting regions.

Flip chip LEDs incorporate multi-layer reflectors and light transmissive substrates patterned along an internal surface adjacent to semiconductor layers. A multi-layer reflector may include a metal layer and a dielectric layer containing conductive vias. Portions of a multi-layer reflector may wrap around a LED mesa including an active region, while being covered with passivation material. A substrate patterned along an internal surface together with a multi-layer reflector enables reduction of optical losses. A light transmissive fillet material proximate to edge emitting surfaces of an emitter chip may enable adequate coverage with lumiphoric material. An emitter chip may be elevated with increased thickness of solder material and/or contacts, and may reduce luminous flux loss when reflective materials are present on a submount. Methods for coating emitter chips with lumiphoric material include one or more of angled spray coating, fillet formation prior to spray coating, stencil island coating, and releasable tape coating.

An optoelectronic device with a multi-layer contact is described. The optoelectronic device can include a n-type semiconductor layer having a surface. A mesa can be located over a first portion of the surface of the n-type semiconductor layer and have a mesa boundary. A n-type contact region can be located over a second portion of the surface of the n-type semiconductor contact layer entirely distinct from the first portion, and be at least partially defined by the mesa boundary. A first n-type metallic contact layer can be located over at least a portion of the n-type contact region in proximity of the mesa boundary, where the first n-type metallic contact layer forms an ohmic contact with the n-type semiconductor layer. A second n-type metallic contact layer can be located over a second portion of the n-type contact region, where the second n-type metallic contact layer is formed of a reflective metallic material.

Techniques are provided for forming a gallium nitride flip-chip light-emitting diode. In an aspect, a device is provided that includes a gallium nitride layer, a passivation layer, a set of first conductive layers, and a second conductive layer. The gallium nitride layer is formed on a substrate that includes a first plurality of recesses associated with a first structure and a second plurality of recesses associated with a second structure, where the first plurality of recesses and the second plurality of recesses are associated with a first conductive material. The set of first conductive layers is formed on the passivation layer and corresponds to the first conductive material. The second conductive layer is formed on the passivation layer and corresponds to a second conductive material.

A light-emitting device comprises a light-emitting stack comprising a first surface, a roughened surface, and a sidewall connecting the first surface and the roughened surface; an electrode structure formed on the roughened surface of the light-emitting stack; a dielectric layer formed on the first surface of the light-emitting stack; a barrier layer covering the dielectric layer; a first reflective electrode between the barrier layer and the first surface of the light-emitting stack; and a passivation layer covering the sidewall of the light-emitting stack and the roughened surface of the light-emitting stack which is not occupied by the electrode structure, wherein the electrode structure is surrounded by the passivation layer, and the passivation layer contacts an surface of the electrode structure and terminates at the surface of the electrode structure.

There is provided an electronic device including at least two diodes each having a mesa structure, including: a first and a second doped semiconductor portion forming a p-n junction, such that a first part of the second doped semiconductor portion located between a second part of the second doped semiconductor portion and the first doped semiconductor portion forms an offset from the second part; a first electrode electrically connected to the first portion, and a second electrode electrically connected to the second portion at an upper face of the second part; and dielectric portions covering side faces of the first portion, the second portion, and the first electrode, wherein upper faces of the first electrode, the second electrode, and the dielectric portions form an approximately plane continuous surface.