Abstract: An optoelectronic device including an array of axial light-emitting diodes. The light-emitting diodes each include an active area configured to emit an electromagnetic radiation having an emission spectrum including a maximum at a first wavelength. The array forms a photonic crystal configured to be able to form three resonance peaks amplifying the intensity of said electromagnetic radiation at at least second, third, and fourth wavelengths.

Abstract: An optoelectronic device including an array of axial light-emitting diodes, the light-emitting diodes each including an active area configured to emit an electromagnetic radiation having an emission spectrum comprising a maximum at a first wavelength, the array forming a photonic crystal configured to form a resonance peak amplifying the intensity of said electromagnetic radiation at at least one second wavelength different from the first wavelength.

Abstract: An optoelectronic device including a matrix of axial light-emitting diodes (LEDs). Each LED includes an active layer emitting electromagnetic radiation. The matrix forms a photonic crystal having at least first and second resonant peaks in a plane containing the active layers, each first and second peak amplifying the radiation intensity at a first and second wavelength respectively. Each light emitting diode includes an elongated semiconductor element, having a first portion of a first average diameter, a second portion extending the first portion and having a cross-sectional area decreasing away from the first portion, and the active layer extending the second portion and having a second average diameter strictly less than the first average diameter, the active layers being located at the first peak locations and absent at the secondary peak locations.

Abstract: A method for manufacturing an optoelectronic device including forming, by metal-organic chemical vapor deposition, MOCVD, wire-shaped, conical, or frustoconical semiconductor elements made of a III-V compound, doped or undoped, each semiconductor element extending along an axis and including a top, and forming by remote plasma chemical vapor deposition, RPCVD, or by molecular-beam epitaxy, MBE, or by hydride vapor phase epitaxy, HVPE, for each semiconductor element, an active area only on said top including at least a first semiconductor layer made of the III-V compound and a second semiconductor layer made of the III-V compound and an additional group-III element.

Abstract: Deposition methods using Cl-based precursors to produce III-nitride materials are generally described.

Abstract: Deposition methods using a Ga-based alloy to incorporate dopants into GaN-based materials are generally described.

Abstract: A method and apparatus for removing deposition products from internal surfaces of a processing chamber, and for preventing or slowing growth of such deposition products. A halogen containing gas is provided to the chamber to etch away deposition products. A halogen scavenging gas is provided to the chamber to remove any residual halogen. The halogen scavenging gas is generally activated by exposure to electromagnetic energy, either inside the processing chamber by thermal energy, or in a remote chamber by electric field, UV, or microwave. A deposition precursor may be added to the halogen scavenging gas to form a deposition resistant film on the internal surfaces of the chamber. Additionally, or alternately, a deposition resistant film may be formed by sputtering a deposition resistant metal onto internal components of the processing chamber in a PVD process.

Abstract: A semiconductor device, such as an LED, includes a plurality of first conductivity type semiconductor nanowire cores located over a support, a continuous second conductivity type semiconductor layer extending over and around the cores, a plurality of interstitial voids located in the second conductivity type semiconductor layer and extending between the cores, and first electrode layer that contacts the second conductivity type semiconductor layer.

Abstract: A semiconductor device, such as an LED, includes a plurality of first conductivity type semiconductor nanowire cores located over a support, a continuous second conductivity type semiconductor layer extending over and around the cores, a plurality of interstitial voids located in the second conductivity type semiconductor layer and extending between the cores, and first electrode layer that contacts the second conductivity type semiconductor layer.

Abstract: Aspects of the invention provide methods and devices. In one embodiment, the invention relates to the growing of nitride semiconductors, applicable for a multitude of semiconductor devices such as diodes, LEDs and transistors. According to the method of the invention nitride semiconductor nanopyramids are grown utilizing a CVD based selective area growth technique. The nanopyramids are grown directly or as core-shell structures.

Abstract: A method of depositing a high quality low defect single crystalline Group III-Nitride film. A patterned substrate having a plurality of features with inclined sidewalls separated by spaces is provided. A Group III-Nitride film is deposited by a hydride vapor phase epitaxy (HVPE) process over the patterned substrate. The HVPE deposition process forms a Group III-Nitride film having a first crystal orientation in the spaces between features and a second different crystal orientation on the inclined sidewalls. The first crystal orientation in the spaces subsequently overgrows the second crystal orientation on the sidewalls and in the process turns over and terminates treading dislocations formed in the first crystal orientation.

Abstract: Methods of epitaxy of gallium nitride, and other such related films, and light emitting diodes on patterned sapphire substrates, and other such related substrates, are described.

Abstract: A semiconductor device, such as an LED, includes a plurality of first conductivity type semiconductor nanowire cores located over a support, a continuous second conductivity type semiconductor layer extending over and around the cores, a plurality of interstitial voids located in the second conductivity type semiconductor layer and extending between the cores, and first electrode layer that contacts the second conductivity type semiconductor layer.

Abstract: Aspects of the invention provide methods and devices. In one embodiment, the invention relates to the growing of nitride semiconductors, applicable for a multitude of semiconductor devices such as diodes, LEDs and transistors. According to the method of the invention nitride semiconductor nanopyramids are grown utilizing a CVD based selective area growth technique. The nanopyramids are grown directly or as core-shell structures.

Abstract: A semiconductor device, such as an LED, includes a plurality of first conductivity type semiconductor nanowire cores located over a support, a continuous second conductivity type semiconductor layer extending over and around the cores, a plurality of interstitial voids located in the second conductivity type semiconductor layer and extending between the cores, and first electrode layer that contacts the second conductivity type semiconductor layer.

Abstract: A layered group III-nitride article includes a single crystal silicon substrate, and a highly textured group III-nitride layer, such as GaN, disposed on the silicon substrate. The highly textured group III-nitride layer is crack free and has a thickness of at least 10 ?m. A method for forming highly textured group III-nitride layers includes the steps of providing a single crystal silicon comprising substrate, depositing a nanostructured InxGa1-xN (1?x?0) interlayer on the silicon substrate, and depositing a highly textured group III-nitride layer on the interlayer. The interlayer has a nano indentation hardness that is less than both the silicon substrate and the highly textured group III-nitride layer.

Abstract: Aspects of the invention provide methods and devices. In one embodiment, the invention relates to the growing of nitride semiconductors, applicable for a multitude of semiconductor devices such as diodes, LEDs and transistors. According to the method of the invention nitride semiconductor nanopyramids are grown utilizing a CVD based selective area growth technique. The nanopyramids are grown directly or as core-shell structures.

Abstract: Methods of epitaxy of gallium nitride, and other such related films, and light emitting diodes on patterned sapphire substrates, and other such related substrates, are described.

Abstract: Methods of epitaxy of gallium nitride, and other such related films, and light emitting diodes on patterned sapphire substrates, and other such related substrates, are described.

Abstract: Techniques for crack-free growth of GaN, and related, films on larger-size substrates via spatially confined epitaxy are described.