A light-emitting device includes a substrate having a top surface, wherein the top surface includes a first portion and a second portion; a first semiconductor stack on the first portion, including a first upper surface and a first side wall; and a second semiconductor stack on the first upper surface, including a second upper surface and a second side wall, and wherein the second side wall connects the first upper surface; wherein the first semiconductor stack includes a dislocation stop layer; and wherein the first side wall and the second portion of the top surface form an acute angle α between thereof.

A method for producing optoelectronic semiconductor components is disclosed. In an embodiment a method includes A) applying radiation-emitting semiconductor chips to an intermediate carrier, wherein the semiconductor chips are volume emitters configured to emit radiation at light exit main sides and on chip side surfaces; B) applying a clear potting permeable to the radiation directly onto the chip side surfaces so that the chip side surfaces are predominantly or completely covered by the clear potting and a thickness of the clear potting in each case decreases monotonically in a direction away from the main light exit sides; C) producing a reflection element so that the reflection element and the clear potting touch on an outer side of the clear potting opposite the chip side surfaces; and D) detaching the semiconductor chips from the intermediate carrier and attaching the semiconductor chips to a component carrier so that the light exit main sides of the semiconductor chips face away from the component carrier.

A dislocation-free GaN/InGaN-based nanowires-LED epitaxially grown on a transparent, electrically conductive template substrate. The simultaneous transparency and conductivity are provided by a thin, translucent metal contact integrated with a quartz substrate. The light transmission properties of the translucent metal contact are tunable during epitaxial growth of the nanowires LED. Transparent light emitting diodes (LED) devices, optical circuits, solar cells, touch screen displays, and integrated photonic circuits can be implemented using the current platform.

Oxygen controlled PVD AlN buffers for GaN-based optoelectronic and electronic devices is described. Methods of forming a PVD AlN buffer for GaN-based optoelectronic and electronic devices in an oxygen controlled manner are also described. In an example, a method of forming an aluminum nitride (AlN) buffer layer for GaN-based optoelectronic or electronic devices involves reactive sputtering an AlN layer above a substrate, the reactive sputtering involving reacting an aluminum-containing target housed in a physical vapor deposition (PVD) chamber with a nitrogen-containing gas or a plasma based on a nitrogen-containing gas. The method further involves incorporating oxygen into the AlN layer.

A method of manufacturing a nitride semiconductor light-emitting element includes: growing an n-side superlattice layer that includes InGaN layers and GaN layers; and, after the step of growing the n-side superlattice layer, growing a light-emitting layer. The step of growing the n-side superlattice layer comprises repeating a cycle n times (n is a number of repetition), the cycle including growing one InGaN layer and growing one GaN layer. In the step of growing the n-side superlattice layer, the step of growing one GaN layer in each cycle from a first cycle to an mth cycle is performed using carrier gas that contains N.sub.2 gas and does not contain H.sub.2 gas. The step of growing one GaN layer in each cycle from a (m+1)th cycle to an nth cycle is performed using gas containing H.sub.2 gas as the carrier gas.

A light emitting diode (LED) array may include a first pixel and a second pixel on a substrate. The first pixel and the second pixel may include one or more tunnel junctions on one or more LEDs. The LED array may include a first trench between the first pixel and the second pixel. The trench may extend to the substrate.

A method includes forming a first n-type nitride semiconductor layer; forming a first light-emitting layer on the first n-type nitride semiconductor layer; forming a first nitride semiconductor layer on the first light-emitting layer by introducing a gas comprising gallium and having a first flow rate; forming a first p-type nitride semiconductor layer on the first nitride semiconductor layer; forming an n-type intermediate layer on the first p-type nitride semiconductor layer; forming a second n-type nitride semiconductor layer on the n-type intermediate layer; forming a second light-emitting layer on the second n-type nitride semiconductor layer; forming a second nitride semiconductor layer on the second light-emitting layer by introducing a gas comprising gallium and having a second flow rate; and forming a second p-type nitride semiconductor layer on the second nitride semiconductor layer. The first flow rate is less than the second flow rate.

Embodiments of the invention include a III-nitride light emitting layer disposed between an n-type region and a p-type region, a III-nitride layer including a nanopipe defect, and a nanopipe terminating layer disposed between the III-nitride light emitting layer and the III-nitride layer comprising a nanopipe defect. The nanopipe terminates in the nanopipe terminating layer.

A light emitting diode (LED) including a first contact. The LED further includes a first semiconductor layer over the first contact. The first semiconductor layer comprises hexagonal Boron Nitride. Additionally, the LED includes a second semiconductor layer over the first semiconductor layer. The second semiconductor layer comprises at least one hexagonal Boron Nitride quantum well and at least one hexagonal Boron Nitride quantum barrier. Moreover, the LED includes a third semiconductor layer over the second semiconductor layer. The third semiconductor layer comprises hexagonal Boron Nitride. Further, the LED includes a second contact over the third semiconductor layer.

An optoelectronic device with a semiconductor body that includes: a bottom cathode structure, formed by a bottom semiconductor material, and having a first type of conductivity; and a buffer region, arranged on the bottom cathode structure and formed by a buffer semiconductor material different from the bottom semiconductor material. The optoelectronic device further includes: a receiver comprising a receiver anode region, which is formed by the bottom semiconductor material, has a second type of conductivity, and extends in the bottom cathode structure; and an emitter, which is arranged on the buffer region and includes a semiconductor junction formed at least in part by a top semiconductor material, different from the bottom semiconductor material.