Strain-enhanced luminescence from biaxially strained Ge light-emitting diodes on GeOI substrates

IF 3.6 2区物理与天体物理 Q2 PHYSICS, APPLIED Applied Physics Letters Pub Date : 2025-04-15 DOI:10.1063/5.0250239

Rongqiao Wan, Lin Zhang, Yuanhao Zhu, Kwang Hong Lee, Qimiao Chen, Fengshuo Wan, Shaoteng Wu, Jun-wei Luo, Chuan Seng Tan

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Abstract

Due to the lack of efficient light sources compatible with complementary metal oxide semiconductor technology, the development of silicon-based photonic integrated circuits has been restricted. Germanium (Ge), with its small bandgap difference between the direct and indirect valleys, becomes a promising candidate for light emission when tensile strain is applied to modify its band structure. However, achieving high and uniform strain in electrically active devices remains a challenge. In this work, we present a biaxially tensile strained Ge light-emitting diode with a vertical p-i-n junction, fabricated on a germanium-on-insulator substrate. The energy difference between the Γ valley and the L valley is further reduced by introducing a biaxial tensile strain of ∼0.77% through the microbridge structure. A 1.7-fold enhancement is observed in the direct bandgap photoluminescence intensity at room temperature. Furthermore, the peak intensity of direct bandgap electroluminescence increases threefold at 400 K compared to room temperature. These results demonstrate the potential of biaxially strained Ge for efficient, Si-compatible light sources, advancing the integration of group-IV materials in silicon photonics.

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GeOI 基底上双轴应变 Ge 发光二极管的应变增强发光

由于缺乏与互补金属氧化物半导体技术兼容的高效光源，制约了硅基光子集成电路的发展。锗（Ge）由于其直接谷和间接谷之间的带隙差小，当施加拉伸应变来改变其能带结构时，它成为一个有希望的发光候选材料。然而，在电活性器件中实现高且均匀的应变仍然是一个挑战。在这项工作中，我们提出了一个具有垂直p-i-n结的双轴拉伸应变锗发光二极管，在绝缘体上的锗衬底上制造。通过微桥结构引入约0.77%的双轴拉伸应变，进一步减小了Γ谷和L谷之间的能量差。在室温下，直接带隙光致发光强度提高了1.7倍。此外，在400 K时，直接带隙电致发光的峰值强度比室温增加了三倍。这些结果证明了双轴应变锗作为高效硅兼容光源的潜力，推进了iv族材料在硅光子学中的集成。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Applied Physics Letters 物理-物理：应用

CiteScore

6.40

自引率

10.00%

发文量

1821

审稿时长

1.6 months

期刊介绍： Applied Physics Letters (APL) features concise, up-to-date reports on significant new findings in applied physics. Emphasizing rapid dissemination of key data and new physical insights, APL offers prompt publication of new experimental and theoretical papers reporting applications of physics phenomena to all branches of science, engineering, and modern technology. In addition to regular articles, the journal also publishes invited Fast Track, Perspectives, and in-depth Editorials which report on cutting-edge areas in applied physics. APL Perspectives are forward-looking invited letters which highlight recent developments or discoveries. Emphasis is placed on very recent developments, potentially disruptive technologies, open questions and possible solutions. They also include a mini-roadmap detailing where the community should direct efforts in order for the phenomena to be viable for application and the challenges associated with meeting that performance threshold. Perspectives are characterized by personal viewpoints and opinions of recognized experts in the field. Fast Track articles are invited original research articles that report results that are particularly novel and important or provide a significant advancement in an emerging field. Because of the urgency and scientific importance of the work, the peer review process is accelerated. If, during the review process, it becomes apparent that the paper does not meet the Fast Track criterion, it is returned to a normal track.