Abstract: An improved process for forming a UV emitting diode is described. The process includes providing a substrate. A super-lattice is formed directly on the substrate at a temperature of at least 800 to no more than 1,300° C. wherein the super-lattice comprises AlxInyGa1-x-yN wherein 0<x?1, 0?y?1 and 0<x+y?1. A first conductive layer with a first type of conductivity is formed on the super-lattice wherein the first conductive layer comprises AlxInyGa1-x-yN wherein 0<x?1, 0?y?1 and 0<x+y?1. A quantum well region is formed on the first conductive layer wherein the quantum well region comprises AlxInyGa1-x-yN wherein 0<x?1, 0?y?1 and 0<x+y?1. A second conductive layer is formed on the quantum well with a second type of conductivity wherein the second conductive layer comprises AlxInyGa1-x-yN wherein 0<x?1, 0?y?1 and 0<x+y?1.

Abstract: A light emitting device with an ultraviolet light-emitting structure having a first layer with a first conductivity, a second layer with a second conductivity; and a light emitting quantum well region between the first layer and second layer. A first electrical contact is in electrical connection with the first layer and a second electrical contact is in electrical connection with the second layer. A template serves as a platform for the light-emitting structure. The template has a micro-undulated buffer layer with AlxInyGa1-x-yN, wherein 0<x?1, 0?y?1 and 0<x+y?1, and a second buffer layer over the micro-undulated buffer layer. The second buffer layer is made of AlxInyGa1-x-yN, wherein 0<x?1, 0?y?1, 0<x+y?1. When an electrical potential is applied to the first electrical contact and the second electrical contact the device emits ultraviolet light.

Abstract: A device for forming a Group III-V semiconductor on a substrate. The device has a primary chamber comprising a substrate and a heat source for heating the substrate to a first temperature. A secondary chamber comprises a metal source and a second heat source for heating the secondary chamber to a second temperature. A first source is provided which is capable of providing HCl to the secondary chamber wherein the HCl and the metal form metal chloride. A metal-organic source is provided. A metal chloride source is provided which comprises a metal chloride. At least one of the metal chloride, the metal-organic and the second metal chloride react with the nitrogen containing compound to form a Group III-V semiconductor on the substrate.

Abstract: An improved high breakdown voltage semiconductor device and method for manufacturing is provided. The device has a substrate and a AlaGa1-aN layer on the substrate wherein 0.1?a?1.00. A GaN layer is on the AlaGa1-aN layer. An In1-bGabN/GaN channel layer is on the GaN layer wherein 0.1?b?1.00. A AlcIndGa1-c-dN spacer layer is on the In1-bGabN/GaN layer wherein 0.1?c?1.00 and 0.0?d?0.99. A AleIn1-eN nested superlattice barrier layer is on the AlcIndGa1-c-dN spacer layer wherein 0.10?e?0.99. A AlfIngGa1-f-gN leakage suppression layer is on the AleIn1-eN barrier layer wherein 0.1?f?0.99 and 0.1?g?0.99 wherein the leakage suppression layer decreases leakage current and increases breakdown voltage during high voltage operation. A superstructure, preferably with metallic electrodes, is on the AlfIngGa1-f-gN leakage suppression layer.

Abstract: Ultraviolet light emitting illuminator, and method for fabricating same, comprises an array of ultraviolet light emitting diodes and a first and a second terminal. When an alternating current is applied across the first and second terminals and thus to each of the diodes, the illuminator emits ultraviolet light at a frequency corresponding to that of the alternating current. The illuminator includes a template with ultraviolet light emitting quantum wells, a first buffer layer with a first type of conductivity and a second buffer layer with a second type of conductivity, all deposited preferably over a strain-relieving layer. A first and second metal contact are applied to the semiconductor layers having the first and second type of conductivity, respectively, to complete the LED. The emission spectrum ranges from 190 nm to 369 nm. The illuminator may be configured in various materials, geometries, sizes and designs.

Abstract: A light emitting device with a template comprising a substrate and a nested superlattice. The superlattice has Al1-x-yInyGaxN wherein 0?x?? and 0?y?1 with x increasing with distance from said substrate. An ultraviolet light-emitting structure on the template has a first layer with a first conductivity comprising Al1-x-yInyGaxN wherein ??x; a light emitting quantum well region above the first layer comprising Al1-x-yInyGaxN wherein ??x?b; and a second layer over the light emitting quantum well with a second conductivity comprising Al1-x-yInyGaxN wherein b?x. The light emitting device also has a first electrical contact in electrical connection with the first layer, a second electrical contact in electrical connection with the second layer; and the device emits ultraviolet light.

Abstract: A low resistance light emitting device with an ultraviolet light-emitting structure having a first layer with a first conductivity, a second layer with a second conductivity; and a light emitting quantum well region between the first layer and second layer. A first electrical contact is in electrical connection with the first layer and a second electrical contact is in electrical connection with the second layer. A template serves as a platform for the light-emitting structure. The ultraviolet light-emitting structure has a first layer having a first portion and a second portion of AlXInYGa(1-X-Y)N with an amount of elemental indium, the first portion surface being treated with silicon and indium containing precursor sources, and a second layer. When an electrical potential is applied to the first layer and the second layer the device emits ultraviolet light.

Abstract: An ultraviolet light emitting semiconductor chip, its use in a LED, and methods of its fabrication are disclosed. The semiconductor chip can include a buffer layer of AlxGa1-xN, where 0<×?1 having a thickness from about 10 ?m to about 3 mm and defining apertures in the thickness of the buffer layer formed due to lateral overgrowth of the buffer layer over a grooved basal substrate. A n-junction LED layer overlying the buffer layer, a multiple quantum well LED layer overlying the n-junction LED layer, and a p-junction LED layer overlying the multiple quantum well LED layer are also included in the chip, where all of the LED layers comprise AlxGa1-xN, where 0<×?1.

Abstract: Methods of achieving high breakdown voltages in semiconductor devices by suppressing the surface flashover using high dielectric strength insulating encapsulation material are generally described. In one embodiment of the present invention, surface flashover in AlGaN/GaN heterostructure field-effect transistors (HFETs) is suppressed by using high dielectric strength insulating encapsulation material. Surface flashover in as-fabricated III-Nitride based HFETs limits the operating voltages at levels well below the breakdown voltages of GaN.

Abstract: An improved solution for producing nitride-based heterostructure(s), heterostructure device(s), integrated circuit(s) and/or Micro-Electro-Mechanical System(s) is provided. A nitride-based etch stop layer that includes Indium (In) is included in a heterostructure. An adjacent layer of the heterostructure is selectively etched to expose at least a portion of the etch stop layer. The etch stop layer also can be selectively etched. In one embodiment, the adjacent layer can be etched using reactive ion etching (RIE) and the etch stop layer is selectively etched using a wet chemical etch. In any event, the selectively etched area can be used to generate a contact or the like for a device.

Abstract: Nitride-based film is grown using multiple precursor fluxes. Each precursor flux is pulsed one or more times to add a desired element to the nitride-based film at a desired time. The quantity, duration, timing, and/or shape of the pulses is customized for each element to assist in generating a high quality nitride-based film.

Abstract: Nitride-based film is grown using multiple precursor fluxes. Each precursor flux is pulsed one or more times to add a desired element to the nitride-based film at a desired time. The quantity, duration, timing, and/or shape of the pulses is customized for each element to assist in generating a high quality nitride-based film.

Abstract: An improved solution for producing nitride-based heterostructure(s), heterostructure device(s), integrated circuit(s) and/or Micro-Electro-Mechanical System(s) is provided. A nitride-based etch stop layer that includes Indium (In) is included in a heterostructure. An adjacent layer of the heterostructure is selectively etched to expose at least a portion of the etch stop layer. The etch stop layer also can be selectively etched. In one embodiment, the adjacent layer can be etched using reactive ion etching (RIE) and the etch stop layer is selectively etched using a wet chemical etch. In any event, the selectively etched area can be used to generate a contact or the like for a device.

Abstract: A heterostructure semiconductor device that includes a composite layer between an active layer and a gate. The composite layer includes a strain matching layer and a barrier layer. The strain matching layer reduces the strain between the barrier layer and the active layer. The device can incorporate various additional layers as well as gate and/or contact configurations to obtain desired device performance characteristics.

Abstract: A heterostructure semiconductor device that includes a composite layer between an active layer and a gate. The composite layer includes a strain matching layer and a barrier layer. The strain matching layer reduces the strain between the barrier layer and the active layer. The device can incorporate various additional layers as well as gate and/or contact configurations to obtain desired device performance characteristics.