Study of quantum well mixing induced by impurity-free vacancy in the primary epitaxial wafers of a 915 nm semiconductor laser

IF 4.8 4区 物理与天体物理 Q2 PHYSICS, CONDENSED MATTER
Tianjiang He, Suping Liu, Wei Li, Li Zhong, Xiaoyu Ma, Cong Xiong, Nan Lin, Zhennuo Wang
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引用次数: 1

Abstract

Abstract Output power and reliability are the most important characteristic parameters of semiconductor lasers. However, catastrophic optical damage (COD), which usually occurs on the cavity surface, will seriously damage the further improvement of the output power and affect the reliability. To improve the anti-optical disaster ability of the cavity surface, a non-absorption window (NAW) is adopted for the 915 nm InGaAsP/GaAsP single-quantum well semiconductor laser using quantum well mixing (QWI) induced by impurity-free vacancy. Both the principle and the process of point defect diffusion are described in detail in this paper. We also studied the effects of annealing temperature, annealing time, and the thickness of SiO 2 film on the quantum well mixing in a semiconductor laser with a primary epitaxial structure, which is distinct from the previous structures. We found that when compared with the complete epitaxial structure, the blue shift of the semiconductor laser with the primary epitaxial structure is larger under the same conditions. To obtain the appropriate blue shift window, the primary epitaxial structure can use a lower annealing temperature and shorter annealing time. In addition, the process is less expensive. We also provide references for upcoming device fabrication.
915nm半导体激光器初级外延片中无杂质空位诱导量子阱混合的研究
输出功率和可靠性是半导体激光器最重要的特性参数。然而,通常发生在腔体表面的灾难性光损伤(COD)将严重损害输出功率的进一步提高,影响可靠性。为了提高腔面抗光灾害能力,利用无杂质空位诱导的量子阱混合(QWI),对915 nm InGaAsP/GaAsP单量子阱半导体激光器采用非吸收窗(NAW)。本文详细介绍了点缺陷扩散的原理和过程。我们还研究了退火温度、退火时间和sio2薄膜厚度对初等外延结构半导体激光器量子阱混合的影响。我们发现,在相同条件下,与完全外延结构相比,初级外延结构的半导体激光器的蓝移更大。为了获得合适的蓝移窗,初级外延结构可以采用较低的退火温度和较短的退火时间。此外,该过程的成本更低。我们也为即将到来的设备制造提供参考。
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来源期刊
Journal of Semiconductors
Journal of Semiconductors PHYSICS, CONDENSED MATTER-
CiteScore
6.70
自引率
9.80%
发文量
119
期刊介绍: Journal of Semiconductors publishes articles that emphasize semiconductor physics, materials, devices, circuits, and related technology.
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