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2.0 μm附近模拟呼吸气体中~(13)CO_2/~(12)CO_2同位素丰度的高精度实时在线测量
Highly precise and real-time measurements of ~(13)CO_2/~(12)CO_2 isotopic ratio in breath using a 2 μm diode laser

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孙明国 1,2   马宏亮 3   刘强 1   曹振松 1 *   王贵师 4   刘锟 4   黄印博 1   高晓明 4   饶瑞中 1  
文摘 采用可调谐二极管激光吸收光谱技术,结合一新型多通池搭建了一套模拟呼吸气体中CO_2同位素丰度的测量装置.气体的压强、温度和流速被很好地控制且均能保持长期的稳定性;采用三次多项式拟合光谱基线,对光谱进行归一化,很好地消除了功率变化对测量结果的影响;利用移窗-回归技术消除频率漂移对同位素丰度测量的影响.实验结果表明:移窗-回归法的引入不仅延长了系统的稳定时间,还提高了系统的测量精度;小波去噪的应用获得了比多光谱平均法高2倍的信噪比;系统的稳定时间为100 s;Kalman滤波后系统测量精度为0.067‰.
其他语种文摘 Real-time breath gas analysis with high accuracy, precision and time resolution, as a promising, non-invasive, fast and reliable tool, is important in medical diagnostics. Especially stable isotopologues of carbon dioxide is applied to multiple research areas including the diagnosis of gastrointestinal diseases. Helicobacter pylori (H. pylori) is one of the most frequent bacterial infectious diseases in human beings and is now recognized as one of the key risk factors for chronic gastritis, peptic ulcers, stomach cancer and lymphoma. In contrast to traditional invasive tests, the most reliable non-invasive method in the diagnosis of the H. pylori infection is considered to be ~(13)C-urea breath test which is implemented by measuring the ~(13)CO_2/~(12)CO_2 isotope ratio in human breath. Tunable diode laser absorption spectroscopy (TDLAS) has the advantages of fast response, low drift, good gas selectivity and high detection sensitivity, and it is very convenient to develop a high precision, real-time and online measurement system. A precision laser spectrometer for the measurement of CO_2 isotope abundance in human breath (with CO_2 concentration of 4%-5%) or high concentration gas is designed and evaluated based on TDLAS technology. The spectrometer contains a novel compact dense-pattern multipass cell with a small volume of 280 cm~3 and an effective optical path length of 26.4 m. The cell is in conjunction with a fiber-coupled distributed feedback diode laser operating at 2.008 μm. Wavelength modulation spectroscopy approach is used. The mass flow, pressure and temperature of the cell are actively controlled, and able to keep long-term stability. The influence of laser power fluctuation is eliminated by fitting the baseline with cubic polynomial to normalize the raw spectrum. Moving window regression is used to remove the influence of frequency drift on measuring isotope abundance. The system measurement precision is improved by wavelet denosing and Kalman filtering. The experimental results demonstrate that moving window regression method not only extends the stability time of the system but also improves the measurement precision of isotope abundance well, the wavelet denoising improves the signal-to-noise ratio by 2 times that by the method of multi-spectral average, the stability time of the system is 100 s given by Allan variance, and the measurement precision of CO_2 isotope ratio is 0.067‰ after Kalman filtering. The use of small multi-pass cell and the default of denoising devices make the system more portable and improve the real-time and online measurement performance of the system. In addition to the measurement of ~(13)CO_2/~(12)CO_2 isotope ratio in human breath, by replacing different lasers, the spectrometer can also be used to measure trace gas concentration and the stable isotope abundance of many gas molecules in atmosphere. Therefore, the spectrometer will have broad applications in the areas of medical diagnosis, carbon cycle study and environmental monitoring.
来源 物理学报 ,2018,67(6):064206-1-064206-09 【核心库】
DOI 10.7498/aps.67.20171861
关键词 激光吸收光谱 ; 稳定同位素 ; 呼吸气体 ; 精确度
地址

1. 中国科学院大气成分与光学重点实验室, 中国科学院大气成分与光学重点实验室, 合肥, 230031  

2. 安徽工程大学数理学院, 芜湖, 241000  

3. 安庆师范大学物理与电气工程学院, 安庆, 246011  

4. 中国科学院安徽光学精密机械研究所, 大气物理化学研究室, 合肥, 230031

语种 中文
文献类型 研究性论文
ISSN 1000-3290
学科 物理学
基金 国家重点研发计划 ;  国家自然科学基金 ;  中国科学院青年创新促进会项目 ;  安徽省高校省级自然科学研究项目
文献收藏号 CSCD:6205661

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引证文献 3

1 张志荣 基于高灵敏激光吸收光谱技术的稳定气态同位素测量及其应用(特邀) 光子学报,2023,52(3):0352108
CSCD被引 4

2 齐刚 多微管阵列结构腔-原子吸收光谱测量Rb同位素比 物理学报,2023,72(5):053201
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