Performance of deep ultraviolet laser diode based on
well-type ladder electron barrier

doi:10.3969/j.issn.1007-5461.2023.01.007

Abstract

Abstract: In order to effectively reduce the electron leakage of the deep ultraviolet laser diode (DUV-LD) in the active region, a well-type ladder electron blocking layer (EBL) structure is proposed. Crosslight software is used to simulate three different structures of rectangle type EBL, ladder type EBL and well type ladder EBL, compare the energy band diagram, radiation recombination rate, electron hole concentration, PI and VI characteristics of the three structure devices. It is observed that the well ladder type EBL has a better suppression effect on the leakage of electrons, leading to the improved optical and electrical properties of the DUV-LD device.

Key words: laser techniques, deep ultraviolet laser diode, AlGaN, well-type ladder electron barrier; electron leakage

CLC Number:

O472

WEI Shiqin , WANG Yao , WANG Mengzhen , WANG Fang , LIU Junjie , LIU Yuhuai , ∗. Performance of deep ultraviolet laser diode based on well-type ladder electron barrier[J]. Chinese Journal of Quantum Electronics, 2023, 40(1): 62-68.

References

[1]Yufei, Hou, Zhiyou,et al. Performance improvement of AlGaN-based ultraviolet light-emitting diodes by amending inverted-Y-shaped barriers with alternate doped Si and Mg[J]. Superlattices & Microstructures, 2017
[2]Zhang, Y. Y . "Performance Enhancement of Near-UV Light-Emitting Diodes With an InAlN/GaN Superlattice Electron-Blocking Layer." Electron Device Letters, IEEE 33.7(2012):p.994-996.
[3]Xing Z Q , Zhou Y J , Liu Y H , et al. Reduction of electron leakage of AlGaN-based deep ultraviolet laser diodes using an inverse-trapezoidal electron blocking layer[J]. Chinese Physics Letters, 2020, 37(2):027302.
[4]Chia-Lung, Tsai, Hsueh-Hsing, et al. Improving the light output power of DUV-LED by introducing an intrinsic last quantum barrier interlayer on the high-quality AlN template[J]. Solid State Electronics, 2017
[5]Guo W , Xu F , Sun Y , et al. Performance improvement of AlGaN-based deep-ultraviolet light-emitting diodes by inserting single spike barriers[J]. Superlattices and Microstructures, 2016.
[6]张彬彬, 李书平, 李金钗,等. 高Al组分AlGaN基紫外LED结构材料[J]. 厦门大学学报(自然版), 2012, 51(001):17-21.
[7] Wada O . Optoelectronic Integration: Physics, technology and applications[J]. South African Journal of Occupational Therapy, 1994, 43(5):1754-1770.
[8] 张洋, 徐鹏. GaN基激光器的研究进展[J]. 有色金属材料与工程, 2020, 41(1):54.
[9]Li Y , Chen S , Tian W , et al. Advantages of AlGaN-Based 310-nm UV Light-Emitting Diodes With Al Content Graded AlGaN Electron Blocking Layers[J]. IEEE Photonics Journal, 2013, 5:8200309.
[10]Velpula R T , Jain B , Bui T , et al. Improving Carrier Transport in AlGaN Deep UltravioletLight-Emitting Diodes Using a Strip-in-a-BarrierStructure[J]. Applied Optics, 2020, 59.
[11]陈航洋，刘达艺等.高Al 组分Ⅲ族氮化物结构材料及其在深紫外LED 应用的进展[J].物理学进展,2013
[12]Kuo Y K , Chen F M , Chang J Y , et al. Design and Optimization of Electron-Blocking Layer in Deep Ultraviolet Light-Emitting Diodes[J]. IEEE Journal of Quantum Electronics, 2019, 56:1.
[13]Jia H , Yu H , Ren Z , et al. Nearly Efficiency-Droop-Free Algan-Based Deep Ultraviolet Light-Emitting Diode Without Electron Blocking Layer[J]. Journal of Electronic Packaging, 2020.

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Performance of deep ultraviolet laser diode based on well-type ladder electron barrier

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