The light-emitting layer in a semiconductor device is deposited on a textured surface. Allows for higher material quality and improved light extraction efficiency. Achieves higher-quality UV to infrared light-emitting devices than are currently achievable by conventional methods.
技术应用
Nitride-based lighting This technology is available for licensing.
详细技术说明
Researchers at the University of California, Santa Barbara have developed a phosphor-free white light source, where an indium-containing light-emitting layer, as well as subsequent device layers, is deposited on a textured surface. It is possible to develop a device with suitably textured areas that would emit at two or more peak wavelengths, where both peak emission wavelengths are produced primarily from the indium-containing light-emitting layer.
附加资料
Patent Number: US8227820B2 Application Number: US200554271A Inventor: Sharma, Rajat | Pattison, Paul Morgan | Kaeding, John Francis | Nakamura, Shuji Priority Date: 9 Feb 2005 Priority Number: US8227820B2 Application Date: 9 Feb 2005 Publication Date: 24 Jul 2012 IPC Current: H01L003300 | H01L003322 US Class: 257095 | 257089 | 257090 | 257103 | 257E33028 | 257E33034 | 438042 | 438047 Assignee Applicant: The Regents of the University of California Title: Semiconductor light-emitting device Usefulness: Semiconductor light-emitting device Summary: For manufacturing semiconductor light-emitting device. Novelty: Semiconductor light-emitting device manufacture method involves depositing indium containing light-emitting layer and subsequent device layer on textured surface
主要类别
光学
细分类别
发光二极管/有机发光二极管
申请号码
8227820
其他
Background
Typical incandescent light sources, while highly energy-inefficient, have a desirable characteristic broad-emission spectrum and a high color-rendering index. In order to mimic these latter attributes in gallium nitride (GaN) based devices, current state-of-the-art designs have certain disadvantages. The process of down-conversion is inherently inefficient due to the Stokes shift and poor conversion efficiency. The emission spectrum and intensity are highly sensitive to spatial variations in the phosphor composition and thickness, and may vary greatly with emission direction. Finally, while the diode itself may have a long lifetime, phosphors typically degrade with time, resulting in a variation of the emission spectrum with time. Current designs proposing methods to obtain "white" light without the aid of phosphors typically rely on a high-indium content layer deposited under conditions that result in poor material quality.
