地下水检测典型挥发性有机物标准样品研究

依据我国地下水污染现状,研究制备了地下水中典型挥发性有机物(VOCs)质量控制模拟标准样品,包含4种卤代烃和6种苯系物,经过气相色谱/质谱分析检测,均匀性和稳定性良好。组织行业内9家实验室,探索开展水中挥发性有机物检测的协作定值研究。开展不确定度来源分析和量值评定,标准样品的标准值和扩展不确定度(k=2)为:三氯甲烷(60.6±5.4)μg/L、四氯化碳(60.2±7.4)μg/L、三氯乙烯(60.4±5.8)μg/L、四氯乙烯(60.6±7.6)μg/L、苯(60.9±4.2)μg/L、甲苯(60.4±4.8)μg/L、乙苯(60.7±5.0)μg/L、邻二甲苯(60.5±6.2)μg/L、间二甲苯(60.4±6.2)μg/L、对二甲苯(60.4±6.2)μg/L。本标准样品主要用于地下水、地表水和饮用水环境监测工作中质量控制、分析方法验证、仪器性能的核查以及技术人员能力考核等。     

新型乘用车室内空气痕量组分快速检测系统的研制

基于自主研制的真空紫外单光子电离飞行时间质谱仪和在线高精度甲醛分析仪,研制了一套新型乘用车室内空气痕量组分的快速检测系统。通过净化空气对乘用车室内空气进行置换,置换完成后,分别利用在线挥发性有机物质谱仪和在线高精度甲醛分析仪对乘用车室内空气中痕量组分和甲醛进行连续检测。结果表明,苯、甲苯、二甲苯/乙苯、苯乙烯和甲醛在对应浓度范围内具有良好的线性,相关系数(r²)均大于0.99,相对标准偏差均小于5%,检出限分别为1.3×10^-9、0.1×10^-9、0.2×10^-9、0.8×10^-9、0.1×10^-9 mol/mol。采用该方法测定车内空气,结果显示,在短时间内,车内VOCs可快速释放达到释放亚平衡状态,并可得到亚平衡状态下的VOCs浓度及释放速率结果。测试车辆车内空气中待测物质苯、甲苯、二甲苯/乙苯、苯乙烯和甲醛的浓度分别为0.30、8.90、25.10、21.90、15.05μg/m³。该方法无复杂耗时的采样过程,操作简便,能够满足...     

多孔膜萃取/微捕集方法及在线测定水中挥发性有机物

基于多孔膜萃取水中挥发性有机物和微捕集技术,构建了一套水中挥发性有机物(Volatile OrganicCompounds,VOCs)样品前处理装置,可自动、在线、连续完成水中挥发性有机物萃取、富集、热解析,传输给气相色谱分离检测。实验分别对膜萃取材料、萃取温度、萃取时间、吹扫气流速等进行了系统优化,并用于氯仿、1,2-二氯甲烷、四氯化碳、三氯乙烯、甲苯、四氯乙烯、乙苯、氯苯、苯乙烯9种挥发性有机物的检测。研究结果表明,采用膜萃取/微捕集装置,与气相色谱联用,在萃取温度60℃,萃取时间30 min,吹扫气流速8 mL/min条件下,采用氢焰离子化检测器(Flame ionization detector,FID),对氯代烃的检出限达到0.003～0.041μg/L,精确度为2.7%～13.0%,线性相关系数均大于0.9936,适用于在线检测水中挥发性有机物。     

吹扫捕集–气相色谱–质谱法同时测定环境水中101种挥发性有机物

建立吹扫捕集–气相色谱–质谱联用法测定环境水中101种常见挥发性有机物(VOCs)的方法。通过加热吹扫,样品水中的VOCs富集于捕集管中,以DB–624(60 m×0.25 mm,1.4μm)色谱柱分离,内标法定量。结果表明,101种挥发性有机物(VOCs)色谱分离效果良好,质量浓度在0.5~50 ng/mL范围内与色谱峰面积均呈线性关系,高沸点VOCs线性范围较窄。方法定量限(10 S/N)为0.11~0.77 ng/mL,均低于GB 3838–2002《地表水环境质量标准》、GB 5749–2006《生活饮用水卫生标准》及国外相关标准的限值。平均加标回收率在70.3%~123.6%之间,测定结果的相对标准偏差不大于8.8%(n=6)。该方法快速、简便,适用于环境水中挥发性有机化合物的分析检测。     

环境舱-热脱附-气相色谱/质谱联用法测定软体家具面料中40种挥发性有机物

建立了同时检测软体家具面料中40种挥发性有机物的环境舱-热脱附-气质联用(ETC-ATD-GC/MS)检测方法。以Tenax TA吸附管吸附环境舱内不同面料中释放的挥发性有机物,经热脱附仪加热,将挥发性有机物脱附后随载气进入GC/MS进行定性和定量分析。考察了吸附管脱附温度、脱附时间,冷阱温度等不同参数对挥发性有机物的脱附效率的影响。结果表明,40种挥发性有机物在2~200 ng质量范围内呈良好的线性关系,相关系数在09949~0.9999之间,方法的检测限为0.011~0.277μg/m~3。方法回收率为88.0%~109.9%,相对标准偏差在1.5%~9.5%之间。方法适用于不同软体家具面料中挥发性有机物的定量分析。     

水体中挥发性有机污染物的应急监测

建立了以吹扫捕集-气相色谱-质谱法为主的挥发性有机物(VOCs)应急监测方法。采用内标法对环境水体中的VOCs含量进行检测,54种VOCs的回收率为93.7%~136%,相对标准偏差为2.67%~14.2%,检出限为0.07~1.87μg/L。同时应用相对响应因子(RRF)快速定量数据库对水样中VOCs的含量进行估算,通过与内标法测量值比对,验证了数据库用于水体污染事故中VOCs应急监测的可行性。     

顶空固相微萃取-气相色谱-质谱法同时测定饮用水源水中24种VOCs

建立了同时测定饮用水源水中24种挥发性有机物(VOCs)的顶空固相微萃取-气相色谱-质谱法.用75 μm CarboxenTM-Polydimethylsiloxane(CAR-PDMS)固相微萃取柱顶空萃取水样中的VOCs,VOCs用气相色谱-质谱联用仪检测,采用内标法定量.对萃取柱涂层、样品盐度、萃取温度和萃取时间等样品前处理条件进行了优化,VOCs的检出限在0.03～0.31 μg/L之间,线性相关系数r＞0.996(二氯甲烷和三氯甲烷除外).对饮用水源水实际水样0.50μg/L和1.00 μg/L两个加标浓度水平的回收率进行了测定,三氯甲烷回收率均值分别为104％和142％,其余VOCs回收率分别为90.0％～120％和88.0％～110％,除二氯甲烷和三氯甲烷外,其余VOCs测定结果的相对标准偏差均小于15.0％(n=6).该方法适用于饮用水源水中挥发性有机物的监测分析.     

国内首创的SPIMS-1000在线挥发性有机物质谱仪

概述了国内首款具有完全自主知识产权的商品化在线挥发性有机物质谱仪(SPIMS-1000)。SPIMS-1000融合了膜富集、紫外光单光子软电离(SPI)和反射式飞行时间质谱等多种技术,实现了对挥发性有机物(VOCs)及半挥发性有机物(SVOCs)的在线定性定量分析。对其基本原理、仪器设计、分析参数及应用进行了介绍。     

顶空气相色谱-四极杆/静电场轨道阱高分辨质谱法测定复杂基体水样中挥发性有机物

建立了顶空气相色谱-四极杆/静电场轨道阱高分辨质谱(HS-GC-Q/Orbitrap HRMS)方法用于复杂基体水样中56种挥发性有机物(VOCs)的测定。在优化的仪器条件下,采用EI离子源以全扫描方式采集数据,以二氯甲烷-D₂和氟苯作为内标进行定量分析。控制试样基体中NaCl浓度为30%(m/V),甲醇浓度在3%(V/V)以内。取样体积为10.00 mL时,56种VOCs的方法检出限为0.01～0.17μg/L,测定下限(定量限)为0.05～0.69μg/L;采用分段线性回归拟合,56种VOCs在0.2～10μg/L范围内的相关系数(R²)均大于0.998,在10～200μg/L范围内的R2均大于0.995;在2、10和100μg/L添加水平下,回收率为83.5%～129.0%,相对标准偏差为0.4%～13.0%。高重碳酸盐地下水基体中VOCs标准样品测试结果表明,在置信度为99%时,本方法结果与标准样品的特性量值之间无显著性差异。本方法灵敏度高、精密度好、准确度高,优于现有方法,尤其适用于不适宜P&T进样的水样中痕量VOCs的测定...     

大气挥发性有机物实时在线监测的双极性质子转移反应质谱仪研制

大气中挥发性有机物(VOCs)能参与光化学反应,导致臭氧和气溶胶等二次污染物的产生,实时精准地监测VOCs对于大气污染成因研究具有重要意义。在质子转移反应质谱(PTR-MS)研究基础上,本工作研制一套用于大气VOCs实时在线监测的双极性质子转移反应质谱仪(Dipolar proton transfer reaction mass spectrometer,DP-PTR-MS)。相比单一反应离子H_3O~+的常规PTR-MS,DP-PTR-MS中有正负3种反应离子(H_3O~+、OH~-、(CH_3)_2COH~+),可根据实际检测需要选择切换,提高定性能力,并有效扩展检测范围。其中,H_3O~+反应离子用于检测质子亲和势大于H_2O的VOCs;OH~-反应离子可与H_3O~+反应离子配合识别VOCs,还可用于检测CO_2等无机物;(CH_3)_2COH~+反应离子可在排除干扰的情况下准确检测NH_3。利用6种标准气体测定DP-PTR-MS检出限和灵敏度,结果表明,DP-PTR-MS对甲苯的检出限为7×10~(-12)(V/V),对氨气的灵敏度为126.0 cps/10~(-9)(V/V)。利用DP-PTR-MS对合肥市区大气VOCs开展连续78h实时在线监测验证实验,结果表明,DP-PTR-MS可对大气中10~(-12)(V/V)量级VOCs进行长期实时在线监测,可作为大气污染成因研究和痕量VOCs排放监测的重要工具。     

Development of proton-transfer ion trap-mass spectrometry: on-line detection and identification of volatile organic compounds in air

We present a newly developed instrument that uses proton-transfer ion trap-mass spectrometry (PIT-MS) for on-line trace gas analysis of volatile organic compounds (VOCs). The instrument is based on the principle of proton-transfer reaction-mass spectrometry (PTR-MS): VOCs are ionized using PTRs and detected with a mass spectrometer. As opposed to a quadrupole mass filter in a PTR-MS, the PIT-MS instrument uses an IT-MS, which has the following advantages: (1) the ability to acquire a full mass spectrum in the same time as one mass with a quadrupole and (2) extended analytical capabilities of identifying VOCs by performing collision-induced dissociation (CID) and ion molecule reactions in the IT. The instrument described has, at its current status, limits of detection between 0.05 and 0.5 pbbv for 1-min measurements for all tested VOCs. The PIT-MS was tested in an ambient air measurement in the urban area of Boulder, Colorado, and intercompared with PTR-MS. For all measured compounds the degree of correlation between the two measurements was high (r ² > 0.85), except for acetonitrile (CH₃CN), which was close to the limit of detection of the PIT-MS instrument. The two measurements agreed within less than 25%, which was within the combined measurement uncertainties. Automated CID measurements on m/z 59 during the intercomparison were used to determine the contributions of acetone and propanal to the measured signal; both are detected at m/z 59 and thus are indistinguishable in PTR-MS. It was determined that m/z 59 was mainly composed of acetone. An influence of propanal was detected only during a high pollution event. The advantages and future developments of PIT-MS are discussed.     

Novel adsorbent based on multi-walled carbon nanotubes bonding on the external surface of porous silica gel particulates for trapping volatile organic compounds

A novel adsorbent, 3-amino-propylsilica gel-multi-walled carbon nanotubes (APSG-MW), was prepared by chemical bonding multi-walled carbon nanotubes on silica gel. The surface area of APSG-MW was 98 m²/g, and the particle size was between 60 and 80 mesh with the average size of 215.0 μm. The adsorption capability of the new adsorbent to volatile organic compounds (VOCs) was measured. The effect of water to the adsorbent and its stability during storage were also investigated. Duplicate precision (DP) and distributed volume pair (DVP) on the basis of the EPA TO-17 criteria were estimated. The results showed that the sampling precision of the adsorbent was more superior compared to the MWCNTs because of the better air permeability. The new adsorbent was successfully applied in the determination of VOCs in ambient indoor air.     

Determination of volatile organic compounds in urban and industrial air from Tarragona by thermal desorption and gas chromatography-mass spectrometry

This study describes the optimisation of an analytical method to determine 54 volatile organic compounds (VOCs) in air samples by active collection on multisorbent tubes, followed by thermal desorption and gas chromatography-mass spectrometry. Two multisorbent beds, Carbograph 1/Carboxen 1000 and Tenax/Carbograph 1TD, were tested. The latter gave better results, mainly in terms of the peaks that appeared in blank chromatograms. Temperatures, times and flow desorption were optimised. Recoveries were higher than 98.9%, except methylene dichloride, for which the recovery was 74.9%. The method's detection limits were between 0.01 and 1.25 μg m⁻³ for a volume sample of 1200 ml, and the repeatability on analysis of 100 ng of VOCs, expressed as relative standard deviation for n = 3, was lower than 4% for all compounds. Urban and industrial air samples from the Tarragona region were analysed. Benzene, toluene, ethylbenzene and xylenes (BTEX) were found to be the most abundant VOCs in urban air. Total VOCs in urban samples ranged between 18 and 307 μg m⁻³. Methylene chloride, 1,4-dichlorobenzene, chloroform and styrene were the most abundant VOCs in industrial samples, and total VOCs ranged between 19 and 85 μg m⁻³.     

Application of a Self-developed Proton Transfer Reaction-Mass Spectrometer to On-line Monitoring Trace Volatile Organic Compounds in Ambient Air

Real-time and on-line monitoring volatile organic compounds(VOCs) are valuable for real-time evalua- ting air quality and monitoring the key source of pollution. A self-developed proton transfer reaction-mass spectrometer(PTR-MS) was constructed and applied to on-line monitoring trace VOCs in ambient air in Hefei, China. With the help of a self-developed catalytic converter, the background signal of the instrument was detected and the stability of the instrument was evaluated. The relative standard deviation of signal at m/z 21 was only 0.74% and the detection limit of PTR-MS was 97 part per trillion(97×10^-12, volume ratio). As a case of the air monitoring in Hefei, the ambient air at Dongpu reservoir spot was on-line monitored for 13 d with our self-developed PTR-MS. Meanwhile, a solid-phase micro-extraction(SPME) technique coupled to gas chromatography-mass spectrometry/mass spectrometry (GC-MS/MS) was also used for the off-line detection of the air. The results show that our self-developed PTR-MS can be used for the on-line and long-term monitoring of VOCs in air at part per trillion level, and the change trend of VOCs concentration monitored with PTR-MS was consistent with that detected with the conventional SPME-GC-MS. This self-developed PTR-MS can fully satisfy the requirements of air quality monitoring and real-time monitoring of the key pollution sources.     

Passive sampling application to control air quality in interior of new vehicles

The investigation of air pollution is a highly important field of research. Air quality in a vehicle’s interior has attracted growing attention since people spend much of their time in vehicles and those frequently travelling in new cars are exposed to harmful compounds. The main air pollutants inside new vehicles are volatile organic compounds (VOCs), present as a result of interior materials’ de-gassing. Among the sampling methods used in indoor air quality research, active sampling for VOCs collection is one method that has been extensively described and applied. The present study sought to implement passive sampling with Radiello® samplers to collect air samples directly in the car factory. The results from passive sampling were compared with results derived from active sampling using Carbograph 1TD and silicagel coated with 2,4-dinitrophenylhydrazine cartridges, based on previously validated methods. The identification and quantification of organic compounds was performed using gas chromatography with flame ionisation coupled with a mass spectrometer after thermal desorption. Aldehydes were determined by means of high-performance liquid chromatography. In the present study, the results obtained with the use of active and passive methods of air sampling were compared, correlations between the two sampling methods were designated and the repeatability of passive sampling was detailed.     

热脱附-气相色谱-三重四极杆串联质谱法测定环境空气中的挥发性有机物

采用热脱附(TD)结合气相色谱-三重四极杆串联质谱(GC-MS/MS)建立了环境空气中23种挥发性有机物(VOCs)同时检测的分析方法。空气样品通过主动采样的方式富集到装有Tenax-TA填料的热脱附管中,热解吸后在选择反应监测(SRM)模式下用GC-MS/MS进行检测,内标法定量。结果表明,23种VOCs在0.01~1 ng和1~100 ng低、高两个范围内线性关系良好,相关系数(r²)均大于0.99,方法定量限为0.00008~1 μ g/m³。加标水平为2、10和50 ng时,23种VOCs的平均回收率为77%~124%。除了最低加标水平的氯苯,相对标准偏差(RSD, n=6)均小于20%。对市内3个采样点的环境空气进行测定,其中苯、甲苯、乙苯、二甲苯、苯乙烯、1,2,4-三甲基苯和六氯丁二烯均有检出。实验证明,该TD和GC-MS/MS相结合的检测方法具有准确、可靠、灵敏度高等优点,适用于环境空气中VOCs的同时测定。     

Measurement of volatile organic compounds in vehicle exhaust using single-photon ionization time-of-flight mass spectrometry

For the real-time measurements of volatile organic compounds (VOCs) in vehicle exhaust, we employed a vacuum ultraviolet single-photon ionization time-of-flight mass spectrometer (VUV-SPI-TOFMS). Exhaust measurements from gasoline and diesel engine vehicles were performed using a chassis dynamometer. Hydrocarbons such as alkylbenzenes, alkenes, alkanes, and dienes were the major organic compounds present in both gasoline and diesel engine exhaust. The concentrations of organic compounds in gasoline exhaust were higher under running conditions than during idling. The VOC concentrations in diesel exhaust were higher during idling than during running conditions. The VUV-SPI-TOFMS measured composition and emission profiles of many hydrocarbons, including aliphatics and aromatics, in vehicle exhaust simultaneously with real time response.     

热脱附-气相色谱-质谱法测定环境空气中67种挥发性有机物

采用热脱附-气相色谱-质谱法,建立了同时分析环境空气中67种挥发性有机物的分析方法。对比了5种不同填充材料不锈钢吸附管对78种挥发性有机物的吸附能力。填充材料为Tenax TA和Carbograph 1TD的混合填料吸附管对分析物的捕集效果最好,在30 mL/min高纯He气持续吹脱45 min的情况下,未发生穿透（即穿透率小于10%）的化合物达67种,分析物的种类包括芳香烃、脂肪烃、卤代烃和含氧挥发性有机物等。优化了使用该吸附管测定67种目标物时的热脱附条件。在5~100 ng范围内,目标化合物的色谱响应值与其量间具有良好的线性关系,其相关系数（r）均在1.0000~0.9977之间。方法检出限为0.3~2.4 ng,以采样体积1 L计算,检出限为0.3~2.4 μg/m³。加标量为20 ng时,7次重复实验目标化合物回收率均在81.6%~114.9%之间,目标化合物的相对标准偏差为1.2%~10.1%。采用该方法对某车厢内空气进行了检测,检出了包括酯类、卤代烷烃、卤代烯烃以及芳香族化合物在内的19种目标化合物,其范围为1.1~84.1 μg/m³。该方法准确、可靠、灵敏度高,实现了对环境空气中67种目标污染物的准确定量。     

双柱串联–便携式气相色谱法测定室内空气中苯系物

建立双柱串联–便携式气相色谱测法定室内空气中苯系物的方法。利用仪器内部自带的Tenax吸附剂在0.5 L/min流量下采集空气样品100 s,然后仪器迅速升温至400℃左右,对吸附剂进行热解吸进样,以微亚离子检测器(MAID)对室内空气中7种苯系物进行测定。结果表明,色谱条件为MXT–200/MXT–WAX金属毛细管柱串联色谱柱,柱温90℃,柱压103 425 Pa时,分离效果最好,且运行时间短。各组分在19.26~306.7μg/m~3范围内与色谱峰面积的平方根线性关系良好,相关系数r大于0.995。方法检出限为6.40~15.9μg/m~3,空白加标回收率为92%~114%,测定结果的相对标准偏差为6.1%~13.7%(n=6)。采用双柱串联便携式气相色谱法测定室内空气中苯系物具有快速、准确、方便等优点。