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Reduction in Leakage Current and Increase in Efficiency of III-Nitride MicroLEDS

技术优势

Hydrogen-free sidewall passivation No increase in resistivity for p-type layers No decrease in transparency for ITO

技术应用

Smart phones Smart watches “Near eye” devices that require ultra-low current

详细技术说明

Researchers at the University of California, Santa Barbara have developed a way to reduce leakage current and increase the efficiency of III-Nitride microLEDs via ALD sidewall passivation. ALD has atomic-scale control on the deposition rate of dielectrics thin film. The dielectric film is sufficient to passivate the sidewall of LEDs and to reduce leakage current for microLEDs. Furthermore, ALD is a hydrogen-free deposition method which prevents the problem of hydrogen passivation, thus increasing the efficiency of the LEDs.

*Abstract

A way to reduce leakage current and increase the efficiency of III-Nitride microLEDs via ALD sidewall passivation. 

*Principal Investigation

Name: Abdullah Alhassan

Department:

Name: Steven DenBaars

Department:

Name: David Hwang

Department:

Name: Matthew Wong

Department:

其他

Background

Due to the chemical inertness of III-nitrides semiconductor materials, plasma-based dry etching is widely employed to define the mesa structure of LEDs. Due to the high-energy nature of plasma etching, the sidewall of the LED has defects which result in leakage current and reduction of internal quantum efficiency. There are currently techniques to try to minimize these problems. Sidewall passivation using dielectrics has been demonstrated and used to decrease the leakage current and plasma-enhanced chemical vapor deposition (PECVD) is the common technique for deposition dielectrics to passivate the sidewall. However, as the size of LED diminishes, it is easier for hydrogen to diffuse into LEDs, lowering the efficiency. This results in less light being extracted from the LED. MicroLEDs are used in a number of “Near-eye” display devices, which have very low current in order to avoid retina damage. As a result, microLEDs with very low leakage current are desired.

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Tech ID/UC Case

29198/2018-256-0

Related Cases

2018-256-0

国家/地区

美国