Mid-Infrared Sensing Using a Hollow–Core Fiber in a Nonlinear Interferometer

IF 4.4 Q1 OPTICS

Advanced quantum technologies Pub Date : 2024-11-05 DOI:10.1002/qute.202400397

Thomas Produit, Tanmoy Chakraborty, Ang Deng, Leonid Krivitsky, Wonkeun Chang, Anna V. Paterova

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Abstract

Increasing the interaction path length is a well-known method for enhancing the sensitivity of the optical detection system. Hollow–core fibers (HCFs) represent a viable alternative to the traditional multi-path cells offering low optical losses and strong confinement of the optical field. Here, the incorporation of an Antiresonant Hollow–core Fiber (AR-HCF) section into a nonlinear interferometer, where the AR-HCF section serves as a gas-sensing cell operating in the IR range is presented. By exploiting the effect of nonlinear interference, the detection is brought into the more operation-friendly visible range. The detection of methane (CH₄) gas at mid-IR wavelengths within a half-meter section of AR-HCF, with an estimated concentration accuracy of 200 ppm·m is demonstrated. These results represent the combination of two research fields within a single instrument and pave the way for further advancement of quantum-inspired gas sensing techniques.

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在非线性干涉仪中使用中空芯光纤进行中红外传感

增加相互作用路径长度是提高光学探测系统灵敏度的一种众所周知的方法。空芯光纤（hcf）是传统多径光纤的可行替代方案，具有低光损耗和光场的强约束。在这里，将抗谐振空心光纤（AR-HCF）部分集成到非线性干涉仪中，其中AR-HCF部分作为在红外范围内工作的气敏单元。利用非线性干扰的影响，使检测进入更易于操作的可见范围。在AR-HCF半米范围内的中红外波长检测甲烷（CH4）气体，估计浓度精度为200 ppm·m。这些结果代表了两个研究领域在单一仪器中的结合，并为进一步发展量子激发的气体传感技术铺平了道路。

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来源期刊

Advanced quantum technologies

CiteScore

7.90

自引率

0.00%

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