基于可调谐激光吸收光谱技术的二硫化碳中红外光谱参数测量

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英文篇名：Measurement of middle infrared spectroscopic parameters of carbon disulfide based on tunable diode laser absorption spectroscopy 作者：管林强 ; 邓昊 ; 姚路 ; 聂伟 ; 许振宇 ; 李想 ; 臧益鹏 ; 胡迈 ; 范雪丽 ; 杨晨光 ; 阚瑞峰 英文作者：Guan Lin-Qiang;Deng Hao;Yao Lu;Nie Wei;Xu Zhen-Yu;Li Xiang;Zang Yi-Peng;Hu Mai;Fan Xue-Li;Yang Chen-Guang;Kan Rui-Feng;Key Laboratory of Environmental Optics and Technology, Anhui Institute of Optics and Fine Mechanics Hefei Institute of Physical Science, China Academy of Sciences;University of Science and Technology of China;Changchun Institute of Optics, Fine Mechanics and Physics, Chinese Academy of Sciences; 关键词：二硫化碳(CS_2) ; 量子级联激光器 ; 可调谐二极管激光吸收光谱 ; 光谱参数 英文关键词：carbon disulfide(CS_2);;quantum cascade laser;;tunable diode laser absorption spectroscopy;;spectroscopic parameters 中文刊名：WLXB 英文刊名：Acta Physica Sinica 机构：中国科学院合肥物质科学研究院安徽光学精密机械研究所环境光学与技术重点实验室;中国科学技术大学;中国科学院长春光学精密机械与物理研究所; 出版日期：2019-04-23 出版单位：物理学报 年：2019 期：v.68 基金：国家重点研发计划(批准号:2016YFC201100)资助的课题~~ 语种：中文; 页：WLXB201908013 页数：7 CN：08 ISSN：11-1958/O4 分类号：125-131

摘要

采用4.6μm附近的量子级联激光器作为光源,搭建了一套二硫化碳(CS2)吸收光谱测量系统,结合可调谐二极管激光吸收光谱技术,对光谱范围为2178.99—2180.79 cm-1的CS2吸收光谱展开了深入研究,重点测量了2180.5—2180.74 cm~(-1)的四条吸收谱线,利用基于非线性最小二乘的多元线性回归算法对CS2吸收光谱进行拟合,精确得到了该范围内谱线的中心波长、线强以及空气展宽系数等光谱参数.经计算,对应谱线线强不确定度小于5%,空气展宽系数不确定度小于15%,这个结果可作为免标定CS2红外光谱探测的基础光谱参数,对痕量CS2气体传感具有重要意义.未来我们将进一步开展2170—2200 cm-1整个谱段的CS2谱线参数的测量,以期填补其在HITRAN和GEISA数据库光谱参数的空白.
        Carbon disulfide(CS_2) is a toxic volatile sulfur compound with flammability and harmfulness, which can seriously harm the human health and threaten the industrial production safety. Therefore, it is of high importance for monitoring CS_2 concentration in the air. Tunable diode laser absorption spectroscopy is very suitable for the detection of trace gas for it possesses high sensitivity and fast response. And the precise knowledge of spectroscopic parameters is essential for deducing the CS_2 concentration. However, primary database including HITRAN and GEISA lacks spectroscopic parameters of CS_2. Thus, to address this issue, a measurement system of absorption spectrum is built for determining spectroscopic parameters by using a quantum cascade laser with narrow linewidth and high output power operating near 4.6 um as a light source. In this paper, direct absorption spectroscopy is used to measure the CS_2 absorption spectra under different sample pressures and the environment temperature is controlled at 296 K, which is adjusted by an air conditioner. We intensively study the absorption spectra of CS_2 in a range between 2178.99 and 2180.79 cm~(-1).According to the relevant reports and the need of actual measurement, four absorption lines are mainly measured in a range of2180.5-2180.74 cm~(-1). Combining with the multiple linear regression algorithm based on the nonlinear leastsquare method and Beer-Lambert law, the integrated area and Lorentz line width of measured CS_2 absorption spectrum can be determined. Then the spectroscopic parameters including absorption line intensity and air broadening coefficient are precisely obtained by linearly fitting the integrated areas and Lorentz line widths of CS_2 absorption spectra at different pressures. Moreover, nitrous oxide(N20) absorption spectrum with high spectral resolution is measured to calibrate the central position of carbon disulfide absorption line according to its known line position extracted from HITRAN database and the results obtained by etalon. The calculated results show that the uncertainty of line intensity and air broadening coefficient are less than 5% and 15%,respectively. It demonstrates that the measured spectroscopic parameters of four absorption lines for this study can be recorded in the database of HITRAN, which is very important for trace gas sensing of CS_2. In the future,we will further improve the system for measuring CS_2 absorption line parameters to fill in the gaps in their spectral parameters in HITRAN and GEISA databases.

引文

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