Long-path quartz tuning fork enhanced photothermal spectroscopy gas sensor using a high power Q-switched fiber laser

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Long-path quartz tuning fork enhanced photothermal spectroscopy gas sensor using a high power Q-switched fiber laser

机译：使用高功率Q开关光纤激光器增强光热光谱气体传感器的长路径轨道调整叉

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A long-path quartz tuning fork enhanced photothermal spectroscopy (QEPTS) gas sensor using a Q-switched fiber laser is proposed. A theoretical model is used to describe the process of the long-path QEPTS sensor and the factors that affect its performance. We can conclude that long optical path and high power are beneficial to the QEPTS sensor from the theoretical analysis. And we use our long-path QEPTS sensor for C2H2 detection at the wavelength of 1531.59 nm. With the scanning time of 4 s and the peak pulse power of 127.5 mW, an Allan deviation analysis shows that our sensor has a minimum detection limit (MDL) of 6.1 ppbv at the 48 s integration time and a good linear response (R-square = 0.99796). (C) 2020 Elsevier Ltd. All rights reserved.

机译：提出了一种使用Q开关光纤激光的长路石英调谐叉增强的光热光谱（Qepts）气体传感器。理论模型用于描述长路径Qepts传感器的过程和影响其性能的因素。我们可以得出结论，长光路和高功率对来自理论分析的Qepts传感器有利于Qepts传感器。我们使用我们的长路径Qepts传感器用于C2H2检测，在1531.59 nm的波长下。扫描时间为4 s和峰值脉冲功率为127.5 mw，Allan偏差分析表明，我们的传感器在48秒的集成时间和良好的线性响应下具有6.1 ppbv的最小检测限（MDL）（R-Square = 0.99796）。（c）2020 elestvier有限公司保留所有权利。

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《Measurement》 |2020年第2020期|共5页
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正文语种 eng
中图分类计量学;
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Long-path; QEPTS; Quartz tuning fork; Q-switched fiber laser; Gas detection;

机译：长路径;Qepts;石英调谐叉;Q开关光纤激光;气体检测;

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1. Long-path quartz tuning fork enhanced photothermal spectroscopy gas sensor using a high power Q-switched fiber laser [J] . Measurement . 2020,第期

机译：使用高功率Q开关光纤激光器增强光热光谱气体传感器的长路径轨道调整叉
2. Trace Gas Sensor Based On Quartz Tuning Fork Enhanced Laser Photoacoustic Spectroscopy [J] . K. Liu, J. Li, L. Wang, Applied physics. B, Lasers and optics . 2009,第3期

机译：基于石英音叉增强型激光光声光谱法的痕量气体传感器
3. Ultra-high sensitive acetylene detection using quartz-enhanced photoacoustic spectroscopy with a fiber amplified diode laser and a 30.72 kHz quartz tuning fork [J] . Yufei Ma, Ying He, Ligong Zhang, Applied Physics Letters . 2017,第3期

机译：使用石英增强的光声光谱仪，光纤放大的二极管激光器和30.72 kHz的石英音叉进行超高灵敏度乙炔检测
4. Gas phase photoacoustic spectroscopy in the long-wave IR using quartz tuning forks and amplitude modulated quantum cascade lasers [C] . Michael D. Wojcik, Mark C. Phillips, Bret D. Cannon Optical Methods in the Life Sciences; Progress in Biomedical Optics and Imaging; vol.7 no.40; Proceedings of SPIE-The International Society for Optical Engineering; vol.6386 . 2006

机译：使用石英音叉和调幅量子级联激光器在长波红外中进行气相光声光谱
5. Interaction force microscopy based on quartz tuning fork force sensor [D] . Qin, Yexian 2007

机译：基于石英调谐叉力传感器的相互作用力显微镜
6. Quartz Enhanced Photoacoustic Spectroscopy Based Trace Gas Sensors Using Different Quartz Tuning Forks [O] . Yufei Ma, Guang Yu, Jingbo Zhang, 2015

机译：基于石英增强光声光谱法的痕量气体传感器使用不同的石英音叉
7. Compact all-fiber quartz-enhanced photoacoustic spectroscopy sensor with a 30.72 kHz quartz tuning fork and spatially resolved trace gas detection [O] . Ma Yufei, He Ying, Yu Xin, 2016

机译：紧凑型全光纤石英增强型光声光谱传感器，带有30.72 kHz石英音叉和空间分辨痕量气体检测
8. Remote Fiber Optic Sensor for Gaseous and Liquid Environments Based on Surface Enhanced Raman Spectroscopy (SERS). Phase 1 [R] . Carrabba, M. M., Rauh, R. D. 1988

机译：基于表面增强拉曼光谱（sERs）的气态和液态环境远程光纤传感器。阶段1

Long-path quartz tuning fork enhanced photothermal spectroscopy gas sensor using a high power Q-switched fiber laser

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