Tunnel Junction Devices with Optically-Pumped III-Nitride Layers
- 技术优势
- Easier than electrical injection for producing long wavelength emissionReduced relaxation of high-indium content layersDoping profile can be engineered to optimize the emission wavelengthEasy incorporation of 2-D light-emitting structures
- 技术应用
- LEDsLaser diodes
- 详细技术说明
- Researchers at the University of California, Santa Barbara have developed a method of replacing standard electrical injection of the quantum wells in semiconductor devices with optically-pumping, by coupling a short-wavelength electrically pumped active region to a long-wavelength optically pumped region via a tunnel junction. Optically pumping allows for the creation of multiple quantum wells, thereby reducing the relaxation of high-indium content layers. Epi stacks optimized for optical pumping may be grown at lower temperatures. Additionally, with optically pumping long wavelength quantum wells, the doping profile can be engineering to optimize the emission wavelength.
- *Abstract
-
A method of replacing standard electrical injection of the quantum wells in semiconductor devices with optically-pumping, by coupling a short-wavelength electrically pumped active region to a long-wavelength optically pumped region via a tunnel junction.
- *Principal Investigation
-
Name: Steven DenBaars
Department:
Name: Asad Mughal
Department:
Name: James Speck
Department:
Name: Erin Young
Department:
Name: Robert Farrell
Department:
Name: Stacy Kowsz
Department:
Name: Tal Margalith
Department:
Name: Shuji Nakamura
Department:
Name: Christopher Pynn
Department:
Name: Benjamin Yonkee
Department:
- 其他
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Background
Despite the inherent advantages of growing III-N semiconductor devices on nonpolar and semipolar planes, challenges still remain for the emission of green, yellow, orange, and red light. High-indium content layers are necessary for long emission wavelengths, but are difficult to achieve because the current growth process involves high temperature steps that can degrade high-indium-content layers.
Tech ID/UC Case
27412/2016-324-0
Related Cases
2016-324-0
- 国家/地区
- 美国
