Huiwen Deng, Jae-Seong Park, Xuezhe Yu, Zizhuo Liu, Hui Jia, Haotian Zeng, Junjie Yang, Shujie Pan, Siming Chen, Alwyn Seeds, Mingchu Tang, Peter Smowton, Huiyun Liu
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引用次数: 0
摘要
为了进一步提高 InAs 量子点(QD)激光器在高温下的性能并了解其作用机理,本研究从理论和实验两方面研究了在 165 ℃ 以上的宽温度范围内,在有源区采用直接 n 型掺杂和调制 p 型掺杂相结合技术(即共掺杂)的效果。通过比较共掺杂、调制 p 型掺杂、直接 n 型掺杂和未掺杂的 QD 激光器,发现共掺杂技术可在整个温度范围内显著降低阈值电流密度,并实现稳健的高温运行。此外,还观察到共掺杂在抑制圆态淬火方面的效果与对掺杂相当。通过对激光器进行速率方程仿真,也可以看出掺杂策略的改进。
1.3 µm InAs/GaAs Quantum-Dot Lasers with p-Type, n-Type, and Co-Doped Modulation
To further enhance the performance and understand the mechanism of InAs quantum dot (QD) laser under high temperature, both theoretically and experimentally it is investigated, the effects of the technique of the combination of direct n-type doping and modulation p-type doping, namely co-doping, in the active region for a wide temperature range over 165 °C. Through the comparison of co-doped, modulation p-type doped, direct n-type doped, and undoped QD lasers, it reveals that the co-doping technique provides a significantly reduced threshold current density across the whole temperature range and robust high-temperature operation. Furthermore, it is also observed that the effectiveness of co-doping in suppressing round-state quenching is comparable to that of p-doping. The improvements in the doping strategies are also revealed through the rate equation simulation of the lasers.
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