晶格匹配可调谐波长 GeSn 量子阱激光器结构：理论研究

IF 4.3 2区工程技术 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Journal of Selected Topics in Quantum Electronics Pub Date : 2024-07-29 DOI:10.1109/JSTQE.2024.3434581

Rutwik Joshi;Luke F. Lester;Mantu K. Hudait

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引用次数: 0

摘要

在这项工作中，我们提出了一个初步框架，并给出了设计基于锗硒的量子阱（QW）激光器的数值估算，该激光器可以实现高效率的激光，同时利用单片晶格匹配（LM）InGaAs/GeSn/InGaAs 叠层。GeSn QW 的发射特性在很大程度上取决于量子化能级，因为体带隙会减小，高锡时接近零。降低光源量子效率的一个因素是有源区内存在的缺陷，这些缺陷会导致非辐射性重组。此外，界面上的缺陷也会阻碍带排列，导致载流子束缚的丧失。InGaAs、InAlAs 和精心设计的 LGB 可以与 GeSn 形成较大的带偏移，从而形成 I 型分离约束异质结构（SCH）QW 激光结构，同时实现几乎无缺陷的有源区，适合室温操作，并可扩展到任意数量的 QW。LM 时，InAlAs 和 InGaAs 层分别提供了 ∼1.1eV 和 ∼0.6eV 的较大总带偏移。对于 10 nm GeSn QW SCH 激光器，在发射波长为 2.6 μm 时，阈值电流 (JTH) 可达到 ∼10 A/cm2 ，材料和模态净增益分别为 ∼3000 cm-1 和 ∼40 cm-1。通过自适应设计SCH波导和QW，可以优化InAlAs/InGaAs/GeSn/InGaAs/InAlAs SCH激光器结构的JTH和净增益，使Sn在8%--18%之间。通过自适应波导设计、量化和锡合金化，可以覆盖广泛的应用空间（1.2 μm 至 6 μm）。

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Lattice Matched Tunable Wavelength GeSn Quantum Well Laser Architecture: Theoretical Investigation

In this work, we propose aninitial framework and present numerical estimates for designing a GeSn-based quantum well (QW) laser that can attain efficient lasing, while utilizing a monolithic lattice matched (LM) InGaAs/GeSn/InGaAs stack. GeSn QW emission characteristics depend significantly on the quantized energy level as the bulk bandgap reduces and approaches zero for high Sn. One factor that diminishes the quantum efficiency of light sources is the defects present within the active region, which result in non-radiative recombination. Furthermore, defects at the interface can hinder the band alignment causing loss of carrier confinement. InGaAs, InAlAs and a well-designed LGB can provide large band offsets with GeSn to form a type I separate confinement heterostructure (SCH) QW laser structure while enabling a virtually defect-free active region suitable for room temperature operation and scalable to an arbitrary number of QWs. When LM, the InAlAs and InGaAs layers provide a large total band offset of ∼1.1eV and ∼0.6eV, respectively. For a 10 nm GeSn QW SCH laser, a threshold current (J _TH ) of ∼10 A/cm ² can be achieved at an emission wavelength of ∼2.6 μm with a net material and modal gain of ∼3000 cm ⁻¹ and ∼40 cm ⁻¹ , respectively. The J _TH and net gain can be optimized for the InAlAs/InGaAs/GeSn/InGaAs/InAlAs SCH laser structure for Sn between 8--18% by adaptively designing the SCH waveguide and QW. Through adaptive waveguide design, quantization, and Sn alloying, a wide application space (1.2 μm to 6 μm) can be covered.

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来源期刊

IEEE Journal of Selected Topics in Quantum Electronics 工程技术-工程：电子与电气

CiteScore

10.60

自引率

2.00%

发文量

212

审稿时长

3 months

期刊介绍： Papers published in the IEEE Journal of Selected Topics in Quantum Electronics fall within the broad field of science and technology of quantum electronics of a device, subsystem, or system-oriented nature. Each issue is devoted to a specific topic within this broad spectrum. Announcements of the topical areas planned for future issues, along with deadlines for receipt of manuscripts, are published in this Journal and in the IEEE Journal of Quantum Electronics. Generally, the scope of manuscripts appropriate to this Journal is the same as that for the IEEE Journal of Quantum Electronics. Manuscripts are published that report original theoretical and/or experimental research results that advance the scientific and technological base of quantum electronics devices, systems, or applications. The Journal is dedicated toward publishing research results that advance the state of the art or add to the understanding of the generation, amplification, modulation, detection, waveguiding, or propagation characteristics of coherent electromagnetic radiation having sub-millimeter and shorter wavelengths. In order to be suitable for publication in this Journal, the content of manuscripts concerned with subject-related research must have a potential impact on advancing the technological base of quantum electronic devices, systems, and/or applications. Potential authors of subject-related research have the responsibility of pointing out this potential impact. System-oriented manuscripts must be concerned with systems that perform a function previously unavailable or that outperform previously established systems that did not use quantum electronic components or concepts. Tutorial and review papers are by invitation only.