基于便携式悬臂梁麦克风光声光谱仪测定温室气体的方法研究

胡玲; 宋兴伟; 张明明; 王如宝

引用本文:	胡玲,宋兴伟,张明明,王如宝.基于便携式悬臂梁麦克风光声光谱仪测定温室气体的方法研究[J].环境监控与预警,2024,16(4):96-101
	HU Ling,SONG Xingwei,ZHANG Mingming,WANG Rubao.Performance Test of Portable Cantilever Beam Microphone Photoacoustic Spectrum Green-house Gas Monitoring Instrument[J].Environmental Monitoring and Forewarning,2024,16(4):96-101

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基于便携式悬臂梁麦克风光声光谱仪测定温室气体的方法研究
胡玲¹，宋兴伟¹，张明明²，王如宝³
1.江苏省环境监测中心，江苏南京 210019；2.南京市鼓楼生态环境监测监控中心，江苏南京 210011；3.北京杜克泰克科技有限公司，北京 100089

摘要:

介绍了一套基于便携式悬臂梁麦克风光声光谱监测大气环境温室气体浓度的高灵敏系统，采用脉冲红外光源通过窄带光学滤光片，形成中红外区的多个光谱波段，结合光学悬臂梁麦克风技术，具有超高灵敏度，可去除背景气体干扰，实现同时监测多种气体。通过对温室气体浓度的测量，验证了甲烷（CH₄ ）的方法检出限为0.226×10^-6，二氧化碳（CO₂ ）的方法检出限为2.624×10^-6，其余的温室气体检出限最低为四氟化碳（0.052×10^-6），最高为三氟化氮（0.164×10^-6）。同时验证了长期重复性，CO₂ 的1倍标准偏差为0.405 5，最大漂移量为1.775 6×10^-6；CH₄ 的1倍标准偏差为9.162 0，最大漂移量为36.261 1×10^-9；该仪器对CO₂ 的最大示值偏差为-0.04×10^-6，CH₄ 的最大示值偏差为1.48×10^-9。温室气体的相对标准偏差均＜2%；CO₂ 和CH₄ 的平均响应时间均为2 min 40 s；CO₂ 和CH₄ 的决定系数（R²）均＞0.999 9，CO₂ 拟合残差在±0.05×10^-6以内，CH₄ 拟合残差在±1×10^-6以内。

关键词: 温室气体光声光谱悬臂梁麦克风多气体检测

DOI：DOI：10.3969/j.issn.1674-6732.2024.04.011

分类号:X831

基金项目:江苏省环境监测科研基金项目（2221，2006）

Performance Test of Portable Cantilever Beam Microphone Photoacoustic Spectrum Green-house Gas Monitoring Instrument

HU Ling¹， SONG Xingwei¹， ZHANG Mingming²， WANG Rubao³

1.Jiangsu Provincial Environmental Monitoring Centre，Nanjing， Jiangsu 210019， China； 2.Nanjing Gulou Ecological Environment Monitoring and Controlling Center， Nanjing， Jiangsu 210011， China； 3.Duke Technology Co.， Ltd.，Beijing 100085， China

Abstract:

This paper introduces a set of highly sensitive system based on portable cantilever beam microphone photoacoustic spectroscopy to monitor the concentration of greenhouse gases in the atmospheric environment. The pulsed infrared light source is used to form multiple spectral bands in the mid infrared region through a narrow band optical filter. Combined with the optical cantilever beam microphone technology， it has ultra high sensitivity and can remove background gas interference to achieve simultaneous monitoring of multiple gases. By measuring the concentrations of greenhouse gases， it was verified that the method detection limit of CH₄ is 0.226×10^-6， and the method detection limit of CO₂ is 2.624×10^-6. The detection limits of other greenhouse gases were as low as CF₄ （0.052×10^-6） and as high as NF₃（0.164×10^-6）. The long-term repeatability was verified， with 1 time the standard deviation of CO₂ being 0.405 5 and the maximum drift being 1.775 6×10^-6； 1 time the standard deviation of CH₄ being 9.162 0 and the maximum drift being 36.261 1×10^-9. It was verified that the maximum indication deviation of the instrument for CO₂ is -0.04×10^-6， and for CH₄ is 1.48×10^-9. The relative standard deviations of greenhouse gases are all <2%； the average response time of CO₂ and CH₄ is verified to be 2 min 40 s； the R² of CO₂ and CH₄ is verified to be>0.999 9， the CO₂ fitting residual is within ±0.05×10^-6， and the CH₄ fitting residual is within ±1×10^-6.

Key words: Greenhouse gases Photoacoustic spectrometry Enhanced cantilever beam optical microphone Multiple gas detection