A semiconductor structure, such as a group III nitride-based semiconductor structure is provided. The semiconductor structure includes a cavity containing semiconductor layer. The cavity containing semiconductor layer can have a thickness greater than two monolayers and a multiple cavities. The cavities can have a characteristic size of at least one nanometer and a characteristic separation of at least five nanometers.

Gallium nitride based devices and, more particularly to the generation of holes in gallium nitride based devices lacking p-type doping, and their use in light emitting diodes and lasers, both edge emitting and vertical emitting. By tailoring the intrinsic design, a wide range of wavelengths can be emitted from near-infrared to mid ultraviolet, depending upon the design of the adjacent cross-gap recombination zone. The innovation also provides for novel circuits and unique applications, particularly for water sterilization.

A semiconductor light emitting device including a substrate, an electrode and a light emitting region is provided. The substrate may have protruding portions formed in a repeating pattern on substantially an entire surface of the substrate while the rest of the surface may be substantially flat. The cross sections of the protruding portions taken along planes orthogonal to the surface of the substrate may be semi-circular in shape. The cross sections of the protruding portions may in alternative be convex in shape. A buffer layer and a GaN layer may be formed on the substrate.

The present invention provides structures and methods that enable the construction of micro-LED chiplets formed on a sapphire substrate that can be micro-transfer printed. Such printed structures enable low-cost, high-performance arrays of electrically connected micro-LEDs useful, for example, in display systems. Furthermore, in an embodiment, the electrical contacts for printed LEDs are electrically interconnected in a single set of process steps. In certain embodiments, formation of the printable micro devices begins while the semiconductor structure remains on a substrate. After partially forming the printable micro devices, a handle substrate is attached to the system opposite the substrate such that the system is secured to the handle substrate. The substrate may then be removed and formation of the semiconductor structures is completed. Upon completion, the printable micro devices may be micro transfer printed to a destination substrate.

A light emitting device including first and second electrodes spaced apart from each other on a substrate, at least one bar-type LED having a first end on the first electrode and a second end on the second electrode, and an insulative support body between the substrate and the bar-type LED. The at least one bar-type LED has a length greater than a width.

A light-emitting device and a manufacturing method thereof are provided. The light-emitting device includes a substrate, an epitaxial blocking layer, and a light-emitting epitaxial structure. The substrate has a surface, in which the surface includes a plurality of protruding parts and a plurality of recess parts relative to the protruding parts. The epitaxial blocking layer disposed on the substrate covers the recess parts and exposes the protruding parts. The light-emitting epitaxial structure disposed on the substrate is connected to the protruding parts and is disposed above the recess parts. The light-emitting epitaxial structure is formed by using the protruding parts as a growth surface thereof so as to have a better crystalline quality.

Integrated active-matrix light emitting pixel arrays based displays are provided. An example integrated device includes a backplane including pixel circuits conductively coupled to an array of light-emitting elements through intermediate conductive layers to form an array of active-matrix light-emitting pixels and a transparent conductive layer on the array of the light-emitting elements. Each of the light-emitting elements includes one or more quantum well semiconductor layers between a first contact electrode and a second contact electrode, and the first contact electrodes of the light-emitting elements is respectively bonded and conductively coupled to the pixel circuits in the backplane via the respective intermediate conductive layers. The transparent conductive layer is in contact with the second contact electrodes of the light-emitting elements to form a common electrode of the light-emitting elements, and a top surface of each of the second contact electrodes is fully in contact with the transparent conductive layer.

A semiconductor substrate structure and process for fabrication of the semiconductor substrate structure are described. The semiconductor substrate structure includes a silicon carbide (SiC) wafer substrate, an active gallium nitride (GaN) layer and a layer of microcrystalline diamond (MCD) layer disposed between the SiC wafer substrate and the GaN active layer. The MCD) layer is bonded to the SiC wafer substrate and to the GaN active layer.

A method of manufacturing a light emitting device can include forming an n-type GaN-based layer on a sapphire substrate; forming a GaN-based active layer on the n-type GaN-based layer; forming a p-type GaN-based layer on the GaN-based active layer; forming a p-type electrode on the p-type GaN-based layer; forming a metal substrate on the p-type electrode; removing the sapphire substrate; forming an n-type electrode on the n-type GaN-based layer; forming a passivation layer on a side surface of the p-type GaN-based layer, a side surface of the GaN-based active layer, a side surface of the n-type GaN-based layer, an upper surface of the n-type GaN-based layer, a side surface of the n-type electrode, and an upper surface of the n-type electrode after the forming the n-type electrode; and forming an open space to expose the n-type electrode by patterning the passivation layer.

A light emitting device can include a metal support structure comprising Cu; an adhesion structure on the metal support structure; a reflective conductive contact on the adhesion structure; a GaN-based semiconductor structure on the reflective conductive contact, in which the GaN-based semiconductor structure includes a first-type semiconductor layer on the metal support structure, an active layer on the first-type semiconductor layer, and a second-type semiconductor layer on the active layer, the GaN-based semiconductor structure includes a bottom surface proximate to the metal support structure, a top surface opposite to the bottom surface, and a side surface between the top surface and the bottom surface, and a first thickness of the GaN-based semiconductor structure from the bottom surface to the top surface is less than 5 micrometers; an interface layer on the GaN-based semiconductor structure; and a contact pad on the interface layer, in which a second thickness of the metal support structure is 0.5 times less than a width of the top surface of the GaN-based semiconductor structure.