Patent application number | Description | Published |
20130214247 | AC LED DEVICE AND ITS MANUFACTURING PROCESS FOR GENERAL LIGHTING APPLICATIONS - The present invention relates to a plurality of light emitting diodes connected in series to elevate the working voltage and to enable the devices to be connected directly to the AC voltage sources. The LED device has five pluralities of series-connected diodes. Four pluralities of series-connected diodes are arranged to at as a rectifier bridge so the fifth plurality of diodes is always forward biased and energized. The light emitting diodes in the device are arranged to accommodate various AC line voltages, diode operating voltages, and diode reverse breakdown voltages. The plurality of diodes was manufactured by first etching epitaxial layer to the insulating substrate to isolate individual diodes, and then use metal lines to interconnect them according to the layout design. The number of die-attach and wire-bonding steps used in the subsequent chip array and lamp manufacturing process is therefore greatly reduced or eliminated. This invention simplifies LED array and lamp process flow, lowers the manufacturing cost, improves product reliability and LED device efficacy. | 08-22-2013 |
20140261660 | TCOs for Heterojunction Solar Cells - Methods are used to develop and evaluate new materials and deposition processes for use as TCO materials in HJCS solar cells. The TCO layers allow improved control over the uniformity of the TCO conductivity and interface properties, and reduce the sensitivity to the texture of the wafer. In Some embodiments, the TCO materials include indium, zinc, tin, and aluminum. | 09-18-2014 |
20150060910 | Conductive Transparent Reflector - Methods to improve the reflection of light emitting devices are disclosed. A method consistent with the present disclosure includes forming a light generating layer over a site-isolated region of a substrate. Next, forming a first transparent conductive layer over the light generating layer. Forming a low refractive index material over the first transparent conductive layer, and in time, forming a second transparent conductive layer over the low refractive index material. Subsequently, forming a reflective material layer thereon. Accordingly, methods consistent with the present disclosure may form a plurality of light emitting devices in various site-isolated regions on a substrate. | 03-05-2015 |
20150091032 | Nickel-Titanium and Related Alloys as Silver Diffusion Barriers - Diffusion of silver from LED reflector layers is blocked by 10-50 nm barrier layers of nickel-titanium (NiTi) alloys. Optionally, the alloys also include one or more of tungsten (W), niobium (Nb), aluminum (Al), vanadium (V), tantalum (Ta), or chromium (Cr). These barriers may omit the noble-metal (e.g., platinum or gold) cap used with silver barriers based on other materials. | 04-02-2015 |
20150093500 | Corrosion-Resistant Silver Coatings with Improved Adhesion to III-V Materials - The electrical and optical performance of silver LED reflective contacts in III-V devices such as GaN LEDs is limited by silver's tendency to agglomerate during annealing processes and to corrode on contact with silver-reactive materials elsewhere in the device (for example, gallium or aluminum). Agglomeration and reaction are prevented, and crystalline morphology of the silver layer may be optimized, by forming a diffusion-resistant transparent conductive layer between the silver and the source of silver-reacting metal, (2) doping the silver or the diffusion-resistant transparent conductive layer for improved adhesion to adjacent layers, or (3) doping the silver with titanium, which in some embodiments prevents agglomeration and promotes crystallization of the silver in the preferred <111> orientation. | 04-02-2015 |
20150311397 | Zinc Stannate Ohmic Contacts for P-Type Gallium Nitride - Transparent ohmic contacts to p-GaN and other high-work-function (≧4.2 eV) semiconductors are fabricated from zinc stannate (e.g., ZnSnO | 10-29-2015 |
20150318446 | Low-Temperature Fabrication of Transparent Conductive Contacts for p-GaN and n-GaN - A ternary transparent conductive oxide, indium zinc oxide (IZO), is formed as a thin film by co-sputtering zinc oxide with indium oxide at a deposition temperature between 25 and 200 C. Optionally, up to 1-2% Al may be added by various methods. The layers may be annealed at temperatures between 200 and 400 C. Measurements of IZO with 75-85 wt % In | 11-05-2015 |
20160111603 | Indium Zinc Oxide for Transparent Conductive Oxide Layer and Methods of Forming Thereof - Provided are light emitting diodes (LEDs) and methods of fabricating such LEDs. Specifically, an LED has an epitaxial stack and current distribution layer disposed on and interfacing the epitaxial stack. The current distribution layer includes indium oxide and zinc oxide such that the concentration of indium oxide is between about 5% and 15% by weight. During fabrication, the current distribution layer is annealed at a temperature of less than about 500° C. or even at less than about 400° C. These low anneal temperature helps preserving the overall thermal budget of the LED while still yielding a current distribution layer having a low resistivity and low adsorption. A particular composition and method of forming the current distribution layer allows using lower annealing temperatures. In some embodiments, the current distribution layer is sputtered using indium oxide and zinc oxide targets at a pressure of less than 5 mTorr. | 04-21-2016 |