The present invention discloses a semiconductor structure with an epitaxial layer and method of manufacturing the same. The semiconductor structure with the epitaxial layer includes a substrate, a blocking layer on the substrate, multiple recesses formed in the substrate, wherein the recess extends along <111> crystal faces of the substrate, and an epitaxial layer on the blocking layer, wherein the epitaxial layer is provided with a buried portion in each recess and an above-surface portion formed on the blocking layer.

A light article includes: a substrate; a truncated cuboidal fin disposed on the substrate and including: a laterally-grown nanocrystal including a longitudinal length and a lateral length that are different; a charge injection facet arranged along a longitudinal fin axis of the truncated cuboidal fin; and a truncation facet disposed opposing the charge injection facet and arranged parallel to the longitudinal fin axis; a side-injector disposed on the charge injection facet of the truncated cuboidal fin and that provides electrons to an active layer; and the active layer interposed between the side-injector and the substrate and that: receives electrons from the side-injector; receives holes from the substrate; and produces light in response to combining the electrons and the holes.

A light emitting diode (LED) device includes a semiconductor layer and one or more portions of a wafer on which the semiconductor layer was formed, the other portions of the wafer having been removed by an etching process. The semiconductor layer has a front surface that includes a light emitting area. The remnants of the wafer on which the semiconductor layer are disposed on the front surface of the semiconductor layer and define a trench. The trench is positioned such that the light emitting area emits light into the trench. The remnants of the wafer make the LED device more robust and the trench may reduce crosstalk with adjacent LED devices.

A micro light emitting diode (LED) device and a method of manufacturing the same are provided. A micro LED device includes a light emitting layer that is provided on a support substrate, a bonding layer, and a driver layer. The light emitting layer includes a stacked structure including a first semiconductor layer, an active layer, and a second semiconductor layer; first and second electrodes provided on a first side and a second side of the stacked structure; and a plurality of light emitting regions. The bonding layer is positioned between the support substrate and the light emitting layer. The drive layer includes a drive element electrically connected to the light emitting layer and is positioned on the light emitting layer to apply power to the plurality of light emitting regions of the light emitting layer.

A method for fabricating and transferring high quality and manufacturable light-emitting devices, such as small sized light-emitting diodes (mLEDs), using epitaxial lateral overgrowth (ELO) and isolation methods. III-nitride ELO layers are grown on a host substrate using a growth restrict mask, and III-nitride device layers are grown on wings of the III-nitride ELO layers. The resulting devices are isolated from the host substrate while attached by a connecting link comprising an epitaxial or non-epitaxial bridge. A regrowth is performed on selected mesas of the device layers to realize improved devices with the help of the bridge. The bridge is broken, and the devices are then plucked from the host substrate and placed on a display panel.

In an embodiment a method for manufacturing a semiconductor body includes providing an subcarrier, generating a layer sequence with a first layer having a doped semiconductor material and a second layer deposited thereon, the second layer having an undoped semiconductor material, providing an electrochemical porosification of the first layer, wherein a degree of porosity is at least 20% by volume, forming mesa structures in the second layer and at least partially in the porous first layer and epitaxially producing a functional layer sequence having at least one planar third layer which is applied to the second layer comprising the mesa structures, wherein the at least one planar third layer has a specific lattice constant which is different from a lattice constant of the second layer.

Solid-state lighting devices including light-emitting diodes (LEDs) and more particularly light-extraction features for LED chips and related methods are disclosed. Light-extraction features include structures formed in or on light-emitting surfaces of substrates. Light-extraction features may include repeating patterns of features with dimensions that, along with reduced substrate thicknesses, provide targeted emission profiles for flip-chip structures, such as Lambertian emission profiles. Dimensions include certain height to width ratios for various substrate thicknesses. Additional light-extraction features with smaller dimensions may be formed along portions or side surfaces of larger light-extraction features.

A substrate for epitaxial growth includes a first surface to be processed, and a second surface opposite to the first surface. When being viewed from above the first surface, the substrate is divided into a modified region and a non-modified region. The modified region is partitioned from the non-modified region by a border which is located at a predetermined position in the substrate, and has a plurality of modified points.

A method for manufacturing a nitride semiconductor light-emitting element includes: forming an n-side layer; forming an active layer on the n-side layer; and forming a p-side layer on the active layer. The step of forming the active layer includes: forming a first layered section comprising a first well layer having a first thickness, and a first barrier layer, at a first temperature, forming a second layered section on the first layered section, the second layered section comprising a second well layer having a thickness greater than the first thickness, and a second barrier layer, at a second temperature lower than the first temperature, and forming a third layered section on the second layered section, the third layered section comprising a third well layer having a third thickness less than the second thickness, and a third barrier layer, at a third temperature higher than the second temperature.

Epitaxial formation structures and associated methods of manufacturing solid state lighting (SSL) devices with target thermal expansion characteristics are disclosed herein. In one embodiment, an SSL device includes a composite structure having a composite CTE temperature dependency, a formation structure on the composite structure, and an SSL structure on the formation structure. The SSL structure has an SSL temperature dependency, and a difference between the composite CTE and SSL temperature dependencies is below 3 ppm/ C. over the temperature range.