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生长在硅衬底上的具有增强电子和空穴注入能力的紫外发光二极管。

UVA light-emitting diode grown on Si substrate with enhanced electron and hole injections.

作者信息

Zhang Zi-Hui, Chu Chunshuang, Chiu Ching Hsueh, Lu Tien Chang, Li Luping, Zhang Yonghui, Tian Kangkai, Fang Mengqian, Sun Qian, Kuo Hao-Chung, Bi Wengang

出版信息

Opt Lett. 2017 Nov 1;42(21):4533-4536. doi: 10.1364/OL.42.004533.

Abstract

In this work, III-nitride based ∼370  nm UVA light-emitting diodes (LEDs) grown on Si substrates are demonstrated. We also reveal the impact of the AlN composition in the AlGaN quantum barrier on the carrier injection for the studied LEDs. We find that, by properly increasing the AlN composition, both the electron and hole concentrations in the multiple quantum wells (MQWs) are enhanced. We attribute the increased electron concentration to the better electron confinement within the MQW region when increasing the AlN composition for the AlGaN barrier. The improved hole concentration in the MQW region is ascribed to the reduced hole blocking effect by the p-type electron blocking layer (p-EBL). This is enabled by the reduced density of the polarization-induced positive charges at the AlGaN last quantum barrier (LB)/p-EBL interface, which correspondingly suppresses the hole depletion at the AlGaN LB/p-EBL interface and decreases the valence band barrier height for the p-EBL. As a result, the optical power is improved.

摘要

在这项工作中,展示了在硅衬底上生长的基于III族氮化物的约370纳米紫外A发光二极管(LED)。我们还揭示了AlGaN量子势垒中AlN成分对所研究LED的载流子注入的影响。我们发现,通过适当增加AlN成分,多量子阱(MQW)中的电子和空穴浓度均得到提高。我们将电子浓度的增加归因于在增加AlGaN势垒的AlN成分时,MQW区域内更好的电子限制。MQW区域中空穴浓度的提高归因于p型电子阻挡层(p-EBL)的空穴阻挡效应降低。这是由于AlGaN最后一个量子势垒(LB)/p-EBL界面处极化诱导正电荷的密度降低,相应地抑制了AlGaN LB/p-EBL界面处的空穴耗尽,并降低了p-EBL的价带势垒高度。结果,光功率得到提高。

相似文献

1
UVA light-emitting diode grown on Si substrate with enhanced electron and hole injections.
Opt Lett. 2017 Nov 1;42(21):4533-4536. doi: 10.1364/OL.42.004533.
3
GaN-based ultraviolet light-emitting diodes with AlN/GaN/InGaN multiple quantum wells.
Opt Express. 2015 Apr 6;23(7):A337-45. doi: 10.1364/OE.23.00A337.

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