13CH4分子v3振动带空气和氮气加宽系数温度依赖性研究

采用中红外波段连续可调谐二极管激光器和自行研制的低温吸收池, 测量了温度为296 K, 252 K, 213 K, 173 K时, 3.38 μm附近¹³CH₄分子的四条跃迁谱线的氮气和空气加宽光谱; 首次通过实验获得空气和氮气对¹³CH₄分子的碰撞加宽系数, 以及谱线加宽系数的温度依赖系数. 实验过程中, 利用Voigt线型对所测量的光谱进行拟合. 实验结果表明, 氮气和空气对¹³CH₄分子的碰撞诱导加宽系数随温度的降低而增大; 相同温度下, 氮气对¹³CH₄分子的碰撞加宽系数普遍大于空气加宽系数. 实验数据为地球和外星体大气遥感探测提供了依据.     

2 μm附近CO2谱线参数测量及应用

吸收光谱技术用于痕量气体浓度监测,特别是在气体分子稳定同位素丰度探测中,吸收谱线参数的准确性非常重要,目前普遍使用的HITRAN数据库中给出的各项参数具有一定的不确定性。为利用2.0 μm激光波段进行CO₂浓度及其同位素丰度探测,需要对该波段的CO₂吸收谱线参数进行校准,采用窄线宽分布反馈式二极管激光器作为光源,结合自行搭建的谱线参数测量系统,采集了2.0 μm波段10条CO₂吸收谱线,获得了各谱线的位置、强度、自加宽系数和N₂加宽系数,并与HITRAN2012数据库中相应的数据进行对比发现两者之间吻合较好,CO₂谱线强度和自加宽系数相对偏差均小于2%。实测实验室大气的CO₂浓度为440 ppm,13CO₂的丰度值δ为-9‰。测量结果为该波段应用于CO₂浓度及13CO₂同位素丰度的实时在线探测提供了重要参考依据。     

2μm波段高灵敏度离轴积分腔装置实际大气CO2测量

利用分布反馈式(DFB)二极管激光器为光源, 搭建了一套2 μm波段的离轴积分腔输出光谱装置. 利用高纯甲烷气体, 测量了腔镜反射率随腔内气体压力 变化的规律. 当腔内压力为3.59 kPa 时, 标定的镜面反射率为0.99865, 在此条件下, 基长55 cm 的离轴积分腔实现了407.4 m的吸收光程. 选取CO₂ 在4993.7431 cm^-1处的吸收谱线对实际大气中的CO₂浓度进行了测量, 探测限为0.53 ppmv (1σ), 利用小波去噪对光谱信号进行了去噪处理, 信噪比提高了80%, 探测限提高到0.29 ppmv(1σ). 利用搭建的装置在实验室内测量了从上午9时到中午12时实际大气中CO₂的浓度, 并与H₂O/CO₂分析仪进行了同时观测与对比分析, 初步验证了测量装置的可靠性.     

脉冲CO2激光器的多频动力学模型

建立了适用于各种气压下(20×133—20×10⁵ Pa)的脉冲CO₂激光器的六温度多频动力学模型，该模型考虑了增益谱线重叠效应，序列带、热带的影响，以及非洛伦兹线型效应.对模型进行数值求解可以预言和解释不同气压下的脉冲CO₂激光器的输出特性，有助于评价不同的抽运设计和研究可调谐特性，为设计脉冲CO₂激光系统提供理论支持. 关键词： 2激光器')" href="#">CO₂激光器 激光动力学 六温度模型 增益谱线重叠     

基于便携式柱面镜多通池的二氧化碳高灵敏度探测研究

二氧化碳作为大气中重要的温室气体，与气候变化和人类活动密切相关，因此对其浓度的探测具有重要意义。利用近红外可调谐二极管激光器结合自主设计的便携式小型化柱面镜光学多通吸收池，实现了二氧化碳气体的高灵敏探测。通过Matlab编写光线传输矩阵，优化设计了基于柱面镜的光学多通吸收池，相比于传统Herriott型多通池，具有腔镜利用面积高、在相同体积内可实现有效光程长等特点，在物理基长为15 cm的情况下，实现了14 m的有效光程。实验中使用中心波长为1.57 μm的DFB二极管激光器，采用直接吸收光谱方法对CO₂气体进行了探测研究，并用Allan方差对系统性能进行了分析。结果表明，在平均时间为5 s时，系统的探测灵敏度为33.1 μL·L-1，平均时间为235 s时，系统的探测灵敏度可达到5.3 μL·L-1。此外，利用该系统实现了大气中CO₂的探测，得到大气中的CO₂浓度为383.4 μL·L-1。基于柱面镜多通池搭建的可调谐激光吸收光谱(TDLAS)系统，结合了柱面镜多通池可在小体积内实现长光程和可调谐激光吸收光谱技术高灵敏度、高分辨率、快速响应的优点，大大减小了系统体积，提高了系统探测灵敏度，在气体探测领域有广泛的应用。     

星载近红外高光谱CO2遥感进展

在应用需求的拉动和高光谱技术发展的驱动下,利用被动式星载近红外高分辨率光谱仪探测大气CO₂分子柱含量已成为一个相当活跃的研究领域。本文介绍了卫星遥感CO₂在科学和社会发展方面的基本需求,分析了被动遥感CO₂的优势和不足;对国际上最新的以美国OCO-2(2014年7月发射)和日本GOSAT(2009年1月发射)为代表的专项CO₂遥感任务进行了综述,包括仪器指标、观测模式和定标模式等方面;着重对OCO-2定标精度需求和多种在轨定标方式进行了阐述;从应用和数据处理角度,简要比较了光栅和傅里叶干涉探测技术探测CO₂的主要特点;最后对定量反演原理进行了概述,并对这一领域的未来发展进行了展望。     

2.0 μm处CO2高温谱线参数测量研究

研究高温下待测气体的谱线属性, 如谱线强度、自加宽系数、空气加宽系数、温度系数等, 为高温环境中可调谐半导体激光吸收光谱技术反演温度、浓度、速度及其场分布提高精度和可靠性起着十分重要的作用. HITEMP数据库中的数据基本上是理论计算结果, 与实际情况存在相当的误差. 为了获得所选2.0 μm处的可用于燃烧诊断的CO₂谱线参数, 本文采用半导体激光器作为光源, 结合实验室的高温测量系统, 记录了700–1300 K温度范围内所选谱线的高温吸收光谱, 获得了各谱线在相应温度下的谱线强度、自展宽系数及温度系数等谱线参数. 测量得到CO₂的5006.978 cm^-1和5007.7874 cm^-1谱线强度与理论计算值相对误差小于11%; 获得了现有数据库缺少的温度系数和高温下自展宽系数数据. 所有各项参数对以后将要进行的燃烧诊断中的CO₂浓度检测有很大帮助. 关键词： 可调谐半导体激光吸收光谱 高温光谱 自展宽系数 温度系数     

腔增强吸收光谱技术中的腔镜反射率标定方法研究

腔增强吸收光谱技术具有实验装置相对简单、灵敏度高、环境适应性强等特点,是高灵敏吸收光谱技术的重要分支之一,在其应用过程中,腔镜反射率是影响其测量准确性的重要因素。利用2.0 μm可调谐二极管激光器作为光源搭建了一套腔增强吸收光谱测量系统,使用两片反射率为99.9%的高反镜作为腔镜,以CO₂气体在5 001.49 cm-1处的吸收谱线作为研究目标,对两种简单实用的腔镜反射率标定方法进行了对比研究。第一种标定方法利用已知程长多通池作为参考池,通过测量谐振腔和多通参考池的输出吸收信号,比较二者的吸收率推导出腔增强系统中的有效吸收路径,然后通过镜片反射率和有效吸收路径的关系对腔镜反射率进行标定;第二种标定方法根据理想气体状态方程得到气体分子数密度,并结合数据库中的谱线线强值,实现了对腔镜反射率进行标定。结果表明,方法一中积分腔与参考池测得信号的积分吸收面积之比为10.5,经过多次测量并计算得到积分腔的有效吸收路径与镜片的反射率分别为302.65 m和99.85%,得到大气中CO₂气体的浓度为0.037 3%,与实际大气CO₂的含量相符合,验证了此方法的准确性;该方法的优点是不受样品浓度影响,但因引入新的参考池,需要两池中气体的压强和温度都保持一致,此方法适用于开放式的腔体结构。方法二中测得大气中CO₂分子位于5 001.49 cm-1处吸收光谱,并结合大气中CO₂气体的分子数密度N为9.099×1015 molecule·cm-3,Hitran数据库中该条谱线线强为3.902×10-22 cm·molecule-1,计算得到镜片反射率约为99.84%;此方法优点是结构相较前一种方法更简单,但需要已知被测气体的分子数密度,因此在配置气体的过程中浓度、压力的误差会影响腔镜反射率的标定。由此可见两种镜片标定方法均可精确实现对腔镜反射率的标定,根据两种方法的特点,在实际应用中可选取相应适合的方法作为参考。     

基于傅里叶变换红外光谱法CO2气体碳同位素比检测研究

介绍了基于傅里叶变换红外技术检测CO₂气体碳同位素比的新方法, 详细介绍了如何从HITRAN红外数据库中提取气体标准吸收截面; 介绍了基于非线性最小二乘法反演CO₂气体碳同位素比和整套实验装置的组成及实验步骤. 从理论和实验分析两方面讨论了温度和气压变化对δ¹³CO₂值的影响规律. 对于同一CO₂标准气体, 采用FTIR和同位素质谱法两种技术进行了δ¹³CO₂值对比检测, 两种测量技术的平均值差异仅为0.25%. 从实验结果可以看出, FTIR技术可以实现对CO₂气体碳同位素比的检测.     

探测大气中CO2的Raman激光雷达

基于大气激光后向散射光谱，研究和设计了探测大气CO₂浓度的Raman激光雷达,其发射机采用Nd∶YAG激光的三倍频354.7nm作为工作波长,发射的单脉冲能量350mJ,重复频率20Hz；接收机采用了光电倍增管(量子效率25%)和光子计数器(计数速率200MHz),探测CO₂的Raman散射371.66nm(频移1285cm^-1)信号,(1小时累加)近地面2.5km以内信噪比不小于8.采用组合滤光片来抑制强的354.7nm Mie-Rayleigh后向散射和氧气375.4nm Raman后向散射对信号的严重干扰. 比较分别来自大气CO₂和参考气体N₂的Raman后向散射回波,可反演出大气中CO₂的相对浓度. 关键词： 大气光学 激光雷达 Raman散射光谱 参考气体 Mie-Rayleigh散射     

Use of the optogalvanic effect (OGE) for isotope ratio spectrometry of 13CO2 and 14CO2

The use of isotopic carbon dioxide lasers for determination of carbon (and oxygen) isotope ratios was first demonstrated in 1994. Since then a commercial device called LARA, has been manufactured and used for Helicobacter pylori breath tests using (13)C-labelled urea. The major advantages of the optogalvanic effect compared with other infrared absorption isotope ratio measurement techniques are its lack of optical background and its high sensitivity resulting from a signal gain proportional to laser power. Continuous normalisation using two cells, a standard and sample, lead to high accuracy as well as precision. Recent advances in continuous flow measurement of (13)C/(12)C ratios of CO(2) in air and extensions of the technique to (14)C, which can be analysed as a stable isotope, are described.     

CO在1. 578 μ m的可调谐二极管激光光谱信号小波去噪研究

研究了一氧化碳(CO)近红外波段直接吸收和波长调制信号去噪处理算法。从HATRAN数据库中得到CO气体的吸收信号作为仿真数据,提取直接吸收信号、1-f和2-f解调信号作为原始信号,研究了不同小波基以及不同的分解层数对叠加高斯白噪声的光谱信号去噪的效果。最后利用基长为0.95 m有效光程为55.1 m的Herriott型多光程池对CO在1.578 μm处的第二泛频带P(4)吸收谱线信号进行测量和信号处理,与原始信号相比,经过信号处理过的直接吸收、1-f和2-f解调信号的信噪比都提高1～2个数量级;通过选择不同小波基和优化小波变换层数,增加了系统的抗干扰能力。     

Measuring the 13C/12C isotope ratio in atmospheric CO2 by means of laser absorption spectrometry: a new perspective based on a 2.05-microm diode laser

The potential use of high sensitivity laser absorption spectroscopy for measuring the 13C/12C isotope ratio in atmospheric CO2 has been demonstrated, using a GaSb-based diode laser at 2.05 microm. In this spectral region, the overlapping between relatively strong 12CO2 and 13CO2 absorption features gives rise to several line pairs which are well suitable for a spectroscopic determination of the isotope ratio. Preliminary results have demonstrated that a short-term precision better than 1 per thousand can be easily obtained, for a CO2 concentration of 1000 ppm. We extensively discuss the influence of a possible non-linearity in the detectors' response on the delta-value and suggest an instrumental development that would allow to eliminate this effect.     

Advances in laser-based isotope ratio measurements: selected applications

Small molecules exhibit characteristic ro-vibrational transitions in the near- and mid-infrared spectral regions, which are strongly influenced by isotopic substitution. This gift of nature has made it possible to use laser spectroscopy for the accurate analysis of the isotopic composition of gaseous samples. Nowadays, laser spectroscopy is clearly recognized as a valid alternative to isotope ratio mass spectrometry. Laser-based instruments are leaving the research laboratory stage and are being used by a growing number of isotope researchers for significant advances in their own field of research. In this review article, we discuss the current status and new frontiers of research on high-sensitivity and high-precision laser spectroscopy for isotope ratio analyses. Although many of our comments will be generally applicable to laser isotope ratio analyses in molecules of environmental importance, this paper concerns itself primarily with water and carbon dioxide, two molecules that were studied extensively in our respective laboratories. A complete coverage of the field is practically not feasible in the space constraints of this issue, and in any case doomed to fail, considering the large body of work that has appeared ever since the review by Kerstel in 2004 (Handbook of Stable Isotope Analytical Techniques, Chapt. 34, pp. 759–787). PACS  07.57.-c; 42.55.Px; 42.62.Fi; 93.90.+y; 91.67.Rx; 92.60.H-; 91.40.Zz; 91.62.Xy     

Relative line intensity measurement in absorption spectra using a tunable diode laser at 1.6 μm: application to the determination of 13CO2/12CO2 isotope ratio

The measurement of relative intensities in CO₂ combination bands spectrum is performed using wavelength modulation spectroscopy (WMS) and a DFB (distributed feedback) diode laser operating at 1.6 μm. The diode laser is stabilized with an external Fabry–Pérot interferometer and absorption spectroscopy is performed in a multipass gas cell. A spectrum containing spectral lines of both ¹³CO₂ and ¹²CO₂ isotopic species is recorded. The variation of laser power during frequency scanning and the line shape are taken into account to accurately extract line intensities from experimental data. The isotopic concentration ratio is deduced from the intensity ratio. Both ratios are measured with an accuracy of about 0.5% in pure CO₂. Received: 9 June 2000 / Published online: 8 November 2000     

Biodegradability screening of soil amendments through coupling of wavelength-scanned cavity ring-down spectroscopy to multiple dynamic chambers

A system was developed for the automatic measurements of 13CO? efflux to determine biodegradation of extra carbon amendments to soils. The system combines wavelength-scanned cavity ring down laser spectroscopy (WS-CRDS) with the open-dynamic chamber (ODC) method. The WS-CRDS instrument and a batch of 24 ODC are coupled via microprocessor-controlled valves. Determination of the biodegradation requires a known δ13C value and the applied mass of the carbon compounds, and the biodegradation is calculated based on the 13CO? mixing ratio (ppm) sampled from the headspace of the chambers. The WS-CRDS system provided accurate detection based on parallel samples of three standard gases (13CO? of 2, 11 and 22 ppm) that were measured simultaneously by isotope ratio mass spectrometry (linear regression R2 = 0.99). Repeated checking with the same standards showed that the WS-CRDS system showed no drift over seven months.The applicability of the ODC was checked against the closed static chamber (CSC) method using the rapid biodegradation of cane sugar-δ13C-labeled through C4 photosynthesis. There was no significant difference between the results from 7-min ODC and 120-min CSC measurements. Further, a test using samples of either cane sugar (C4) or beetroot sugar (C3) mixed into standard soil proved the target functionality of the system, which is to identify the biodegradation of carbon sources with significantly different isotopic signatures.     

Diode laser absorption spectrometry for 13CO2/12CO2 isotope ratio analysis: Investigation on precision and accuracy levels

Near-infrared laser spectroscopy is used to measure the ¹³C/¹²C isotope abundance ratio in gas phase carbon dioxide. The spectrometer, developed expressly for field applications, is based on a 2 μm distributed feedback diode laser in combination with sensitive wavelength modulation detection. It is characterized by a simplified optical layout, in which a single detector and associated electronics are used to probe absorptions of a pair of ¹³CO₂ and ¹²CO₂ lines, simultaneously in a sample, as well as a reference gas. For a careful investigation of the achievable precision and accuracy levels, we carried out a variety of laboratory tests on CO₂ samples with different isotopic compositions, calibrated with respect to the international standard material by means of isotope ratio mass spectrometry. The 1-σ accuracy of the ¹³CO₂/¹²CO₂ determinations, reported in the so-called δ notation, is about 0.5‰ (including both statistical and systematic errors), for δ-values in the range from -30‰ to +20‰. We show that the major source of systematic errors is a consequence of the non-linearity of the Lambert–Beer absorption law, and can be corrected for to a very high degree of accuracy. PACS 42.62.Fi; 42.55.Px; 33.20.Ea     

基于中红外量子级联激光器和石英增强光声光谱的CO超高灵敏度检测研究

采用石英增强光声光谱(QEPAS)技术对CO痕量气体展开检测研究. 为了实现超高灵敏度探测, 采用输出波长为4.6 μm的新颖中红外高功率分布反馈量子级联激光器为光源, 实现了对CO气体基频吸收带的激发与测量. 在优化了调制深度、气体压强和提高了CO分子的振动-转动弛豫速率后, 获得了1.95 ppbv的优异探测极限. 在分析检测结果的过程中, 讨论了能级寿命对信号强度的影响, 并对QEPAS信号强度的表达式进行了修正.     

激光共振电离过程中铅同位素歧视效应研究

以速率方程为基础,通过数值模拟方法,对Pb的激光共振电离通道：“6s26p2 3P0—6s26p7s 3P0₁—电离”的激光诱导同位素歧视效应进行了研究,以探讨减小激光诱导歧视效应,准确测定Pb同位素比值的有效途径。通过考虑激光线型、原子吸收谱线线型、同位素位移及同位素超精细结构等因素的影响,对速率方程进行近似。在近似的速率方程基础上,以“1+1”激光共振电离过程为例,进而探讨激光峰值功率密度、带宽和中心波长对Pb的同位素歧视效应的影响。研究结果表明,利用最佳波长法,可基本消除同位素歧视效应的影响;提高激发光光强可使Pb同位素饱和电离,从而消除同位素歧视效应的影响;采用宽带激光激发,可减小同位素歧视效应的影响。