四族纳米线阵列中短波红外吸收的扩展

A. Attiaoui, É. Bouthillier, G. Daligou, A. Kumar, S. Assali, O. Moutanabbir
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引用次数: 3

摘要

在扩展短波红外(e-SWIR)范围内使用可扩展材料的工程光吸收是一种长期追求的能力,对于实现成本效益和高性能传感和成像技术至关重要。在这里,我们展示了增强的、可调谐的e-SWIR吸收,使用由有序阵列的亚稳GeSn纳米线组成的硅集成平台,Sn含量达到9 at。%和可变直径。详细的模拟与实验分析相结合,系统地研究了光- gesn纳米线的相互作用,以定制和优化纳米线阵列的几何参数和相应的光学响应。理论上预测了与直径相关的漏模共振峰,并在1.5 ~ 2.2 {\mu}m的波长范围内进行了实验验证。使用直径为325 nm的纳米线,相对于2.1 {\mu}m的GeSn层的吸收增强了三倍。时域有限差分模拟揭示了e-SWIR增强吸收的潜在机制。在直径大于325 nm处,HE11和HE12谐振模式与纳米线耦合,而在直径较小、波长较长的纳米线处,HE11模式被引导到其下的Ge层。NWs中逐渐变细的存在进一步扩大了吸收范围,同时使反射最小化。这种设计和增强e-SWIR吸收的能力为实现利用全IV群平台的新型光子器件奠定了基础。
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Extended Short-Wave Infrared Absorption in Group-IV Nanowire Arrays
Engineering light absorption in the extended short-wave infrared (e-SWIR) range using scalable materials is a long-sought-after capability that is crucial to implement cost-effective and high-performance sensing and imaging technologies. Herein, we demonstrate enhanced, tunable e-SWIR absorption using silicon-integrated platforms consisting of ordered arrays of metastable GeSn nanowires with Sn content reaching 9 at.% and variable diameters. Detailed simulations were combined with experimental analyses to systematically investigate light-GeSn nanowire interactions to tailor and optimize the nanowire array geometrical parameters and the corresponding optical response. The diameter-dependent leaky mode resonance peaks are theoretically predicted and experimentally confirmed with a tunable wavelength from 1.5 to 2.2 {\mu}m. A three-fold enhancement in the absorption with respect to GeSn layers at 2.1 {\mu}m was achieved using nanowires with a diameter of 325 nm. Finite difference time domain simulations unraveled the underlying mechanisms of the e-SWIR enhanced absorption. Coupling of the HE11 and HE12 resonant modes to nanowires is observed at diameters above 325 nm, while at smaller diameters and longer wavelengths the HE11 mode is guided into the underlying Ge layer. The presence of tapering in NWs further extends the absorption range while minimizing reflection. This ability to engineer and enhance e-SWIR absorption lays the groundwork to implement novel photonic devices exploiting all-group IV platforms.
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