A New Cell for Single Sided Headspace Sampling and Evaluation of Barrier Function in Laminated Paperboard

A new cell for single sided headspace sampling has been developed for the analysis of volatile organic compounds from food packaging paperboard and laminated paperboard. The cell, which samples the volatile organic compounds over a selected surface, is useful for determining the barrier function of laminated paperboards with respect to volatile compounds. The analysis of volatile organic compounds is carried out by purge and trap capillary gas chromatography in combination with mass spectrometric detection and compound identification. The new sampling cell was constructed to facilitate specific analysis of organic compounds from only one side of a laminated paperboard. The construction and the operating principles of the new sampling device are described. The repeatability of the single sided headspace procedure was found to be quite good. Relative standard deviations of about 5–7% were obtained for the major compounds quantified in replicate headspace analyses of a laminated paperboard. The volatile compounds released from the inner side of a food packaging paperboard sample with different surface composition on the two sides were determined. The barrier function against volatile organic compounds of some laminated paperboards was investigated employing the new headspace cell.     

Chromatomembrane Headspace Analysis of Aqueous Solutions at Elevated Temperatures

Both theoretically and experimentally, the effect of temperature has been studied and assessed on analytical characteristics of continuous chromatomembrane gas extraction of volatile organic compounds from aqueous solutions with the aim of their subsequent gas chromatographic determination. It has been found that a rise of temperature up to 80 °C enables reduction of the detection limits of alcohols, ketones, and esters by a factor of 10 to 20. If a water vapor condenser is used in the extractant gas line, then the repeatability of results does not depend on temperature. The conditions have been optimized for the continuous headspace chromatomembrane analysis in combination with gas adsorption (purge and trap) concentration of analytes.

     

吹扫捕集和GC-MS测定水中26种挥发性有机物

用吹扫捕集和气相色谱―质谱联用技术对地表水中的26种挥发性有机污染物进行同时测定。实验结果在2.0～50.0μg/L范围内线性良好,相关系数均大于0.99,检出限在0.08～0.91μg/L范围内。方法的平均回收率为87.33%～116.68%,相对标准偏差(RSD)均小于5%。该方法前处理简单快速,采用内标法定量准确度高,重复性好,适用于清洁水中挥发性有机物的测定。     

Determination of volatile organics in drinking water with USEPA method 524.2 and the ion trap detector

New drinking water regulations require the monitoring of eight volatile organic compounds that have established maximum contaminant levels (MCLs) and 51 other volatile organics for which MCLs are not established. A laboratory analytical method (Method 524.2) for the determination of 58 of these compounds is investigated, and precision and accuracy data are obtained. The method uses a standard inert gas purge extraction, isolation of the volatile organics on a three-stage solid-phase trap, thermal desorption into a gas chromatograph, separation with a fused-silica capillary column, and identification and measurement with a relatively low cost, benchtop ion trap detector that functions as a mass spectrometer. At a concentration of 2 micrograms/L (2 parts per billion), the grand mean measurement accuracy for 54 compounds was 95% of the true value with a mean relative standard deviation (RSD) of 4%. At 0.2 micrograms/L (200 parts per trillion), the grand mean measurement accuracy for 52 compounds was 95% of the true value with a mean RSD of 3%.     

Analysis of volatile organic chemicals in aqueous samples by purge/GC with selective water removal

A gas chromatographic method for volatile organic chemicals in which an aqueous sample is purged directly to a cryogenically cooled, fused silica column uses a Nafion tube drier between the purge vessel and GC column. The Nafion strips water from the gas stream during the purge step while allowing volatile halocarbons and aromatics to continue to the GC column. Examples of this technique are presented on 0.53 mm and 0.25 mm fused silica columns coated with a variety of stationary phases.     

Critical role of a pre‐purge setup in the thermal desorption analysis of volatile organic compounds by gas chromatography with mass spectrometry

In general, volatile organic compounds in ambient air are quantified by following a well‐defined standard calibration procedure using a gas‐/liquid‐phase standard. If the liquid standard is analyzed by a thermal desorption, the solvent effect is unavoidable through the alteration of breakthrough properties or retention times. To learn more about the variables of the thermal desorption‐based analysis, the effect of pre‐purge conditions was evaluated for 18 volatile organic compounds with different types of sorbent tube materials by fixing standard volume (1 μL) and flow rate (100 mL/min). The gas phase calibration was also carried out as reference for the non‐solvent effect. A single tube filled with Tenax TA exhibited the least solvent effect with the short pre‐purge (1 min), while being subject to the breakthrough at or above 10 min pre‐purge. For a three‐bed sorbent tube with Carboxen 1000, at least 10 min of pre‐purge was needed for the compounds with a retention time close to methanol (e.g., propanal). Another three‐bed tube with Carbopack X reduced the solvent effect efficiently for a short pre‐purge (2 min) without the breakthrough. As such, the solvent effect can be adjusted by the proper control of the sorbent tube application.     

新型水蒸气顶空富集装置在饮用水中痕量挥发性有机物非目标筛查中的应用

以饮用水中痕量挥发性有机物(VOCs)非目标筛查为目的,构建了一种新型的大体积水样高倍富集装置。对其精馏管长度、回收冷凝液体积、吸收介质等影响富集效果的关键因素进行了优化。该装置以水蒸气为吹扫气,同时以水作为吸收剂,将1 L水样富集浓缩至5 mL后,可使原有吹扫捕集-气相色谱-质谱法(P&;T-GC-MS)分析VOCs的灵敏度提高1～2个数量级。用该方法对某净水厂的源水与出厂水进行了痕量VOCs的定性分析与比较。与传统P&;T-GC-MS方法相比,本方法对两种水样的污染物检出数目由原来的无检出和5种分别提高至16种和35种。分析结果表明饮用水消毒前后污染物的种类及含量存在显著差异。     

Isolation and preconcentration of volatile organic compounds from water

Methods for the isolation and/or concentration of volatile organic compounds from water samples for trace organic analysis by gas chromatography are reviewed. The following basic groups of methods are discussed: liquid-liquid extraction, adsorption on solid sorbents, extraction with gas (gas stripping and static and dynamic headspace techniques) and membrane processes. The theoretical bases of these methods are discussed. Experimental arrangements for the isolation and/or concentration of volatile compounds from water are presented and discussed with respect to their efficiency. The applicability of the described methods to the isolation and/or concentration of various organic compounds from waters of various origins is discussed.     

Purge and trap/thermal desorption device for the determination of dimethylselenide and dimethyldiselenide

A method is described for the determination of dimethylselenide and dimethyldiselenide using a purge-and-trap/thermal desorption device (PT/TD) coupled to a capillary column gas chromatograph with a six-way Valco valve. The system is constructed in such a way that it allows also on-column injections of the volatile compounds in organic solvents for external calibration purposes without the need to disassemble the PT/TD. The influence of the purge flow, purge time and volume of sample, on the purge efficiency of the PT system is studied. Desorption time and temperature are optimised for the TD mode of operation. Atomic absorption spectrometry (AAS) and flame photometric detection (FPD) have been used for the final determination of the volatile compounds. The figures of merit achieved with both detectors are reported.     

Hydrothermal liquefaction of cypress: Effects of reaction conditions on 5-lump distribution and composition

Effects of reaction temperature, reaction time and water amount on the hydrothermal liquefaction of cypress, were studied in this paper. The reaction system was divided into gas lump, water-soluble oil lump, heavy oil lump, volatile organic compounds lump, and solid residue lump. Results showed that temperature was the critical parameter for 5-lump distribution in the cypress hydrothermal conversion process. The higher temperature and longer reaction time were not usually suitable for the production of bio-oil (water-soluble oil and heavy oil). The increase in the yields of gas and volatile organic compounds was also observed as temperature was increased. However, the yield of the volatile organic compounds increased first, and then decreased with the reaction time and the water amount. High amount of water led to high conversion and bio-oil yield. The FT-IR analysis of the solid residues showed that the major peaks of cypress diminished after 280 °C. The GC–MS analysis showed that the volatile organic compounds, water-soluble oil and heavy oil comprised a mixture of organic compounds of 5–7, 5–10 and 7–26 carbons, respectively, which mainly included furfural, phenol, acids, furans and their derivatives. The WSO had similar elemental compositions but the HO had a higher content of carbon and a lower concentration of oxygen as compared to cypress.     

气提浓缩仪分析水中痕量挥发性有机物研究

本文描述了气提浓缩仪的设计及操作程序用于对水中痕量挥发性有机物的测定。分析物被气提吸附于TenaxGC柱上,然后直接脱附到毛细管气相色谱柱上进行分析,并用FID或MS鉴定。本文除对色谱条件进行优化外,对气提时间和脱附温度等分析操作条件也进行了研究。检测下限为0.01-0.30PPb,峰面积检测精度优于6.9％,对16种化合物的回收率优于74％。     

Automatic system for rapid analysis of volatile compounds by purge-and-cold-trapping/capillary gas chromatography

A system for automatic analysis of volatile compounds by purge-and-cold-trapping/capillary gas chromatography is described. It is suitable for analysis of volatile compounds in a wide variety of samples, such as water, food products and environmental samples. Possibilities and limitations of the system are evaluated in relation to several parameters. The efficiency of different types of cryogenic trap (open tubular, coated, packed) is also investigated; it depends on purge-flow rate, temperature of trapping, and total purge volume. Examples of the analysis of volatile compounds in foods and water are given.     

Isolation and Determination of Volatile Organic Compounds from Water by Dynamic Purge-and-Trap Technique Coupled with Capillary Gas Chromatography

The preconcentration technique of purge-and-trap has been investigated in the present work for quantitative adsorption of volatile organic pollutants purged from water samples. A dynamic purging device with variable volume size has been constructed and tested to purge different concentrations of organic compounds. With Tenax GR as the adsorbent, a dynamic purge-and-trap technique was developed combining on-column preconcentration procedures using ambient trapping/thermal desorption/cryogenic focusing/back-flash injection prior to separation and determination using capillary gas chromatography. Various aromatic compounds in water were determined, giving linear working ranges over five orders of magnitude from 0.02 to 5000 µg/L. The analytical procedures were optimized under the assistance of ultrasonication with results validated for the determination of organic contaminants in underground water and tap water, giving over 93% recoveries and a detection limit of 0.01 µg/L, two orders of magnitude lower than those obtained using commercial available instruments with on-line configuration to minimize cross-contamination. The technique provides a potential automated method for in situ monitoring of volatile organic compounds in water.     

Trace-level determination of 1,4-dioxane in water by isotopic dilution GC and GC-MS

The volatile and polar solvent 1,4-dioxane has recently been reported as a contaminant of ground and surface waters, establishing the need to determine this substance in drinking water. This investigation established that 1,4-dioxane can be determined in water by various techniques including direct aqueous injection (DAI) gas chromatography (GC) and purge and trap GC-mass spectrometry (MS). Purge and trap GC-MS is limited by 1,4-dioxane's poor purge efficiency, resulting in detection limits up to 100 times greater than the efficiently purged volatile organic compounds. To attain the sensitivity required for drinking water monitoring, a method based on continuous liquid-liquid extraction with dichloromethane was developed. Isotope dilution was more accurate and reproducible than quantification with external standards, and the improvement in precision led to a lower method detection limit, 0.2 microgram L-1, using a quadrupole ion trap instrument in the electron ionization mode. Isotope dilution accuracy approached 100% in ppb determinations. Isotopic dilution quantification was also possible using a non-selective GC detector owing to the high efficiency of capillary GC columns that resolve the deuterium-labeled solvent from the natural isotopes.     

Trace level analysis of volatile and semi-volatile organic compounds in water using a membrane/jet separator interfaced to an ion trap mass spectrometer

An ion trap mass spectrometer, equipped with a membrane/jet separator interface, is used for the direct detection of volatile and semi-volatile organic compounds in aqueous solutions. Aqueous sample is passed through a capillary membrane, the outside surface of which is continuously purged by helium. The permeate is pneumatically transported to the mass spectrometer via a jet separator which acts as an additional enrichment device. The performance and response characteristics of non-porous silicone and microporous polytetrafluoroethylene (PTFE) membranes are studied. The microporous membrane allows sufficient water to pass for it to be used as a reagent gas for chemical ionization. Both types of membranes provide detection limits in the parts per trillion (pptr) to parts per billion (ppb) range with a linear dynamic range of 3 orders of magnitude for some volatile organic compounds. Results show that there is no detectable matrix effect on response in the selected cases examined. The use of microporous membranes to analyze more polar compounds, such as 5-hydroxymethyl furfuraldehyde and lactic acid, is also demonstrated. The effects of other experimental parameters, such as membrane temperature and length, on sensitivity are also investigated.     

Implementation and optimisation of a high‐temperature loading strategy of liquid standards in the quantification of volatile organic compounds using solid sorbents

High‐temperature liquid standard loading strategy onto solid sorbent traps for calibration of thermal desorption–GC–MS techniques for the analysis of volatile organic compounds is evaluated and optimised. With this proposed set‐up, volatilised liquid‐loaded standards interact in gas phase with solid sorbent particles. Response factor for 15 volatile compounds with different vapour pressures have been evaluated and compared with common strategies based on liquid matrix interactions. Using gas matrix strategy improves signal output in the range 10–700%. Average increase for benzene, toluene, ethylbenzene and xylenes is 480%. Reported systematic bias between liquid standards and gas samples are reduced, enhancing thermal desorption methodologies on one of its more important issues. In addition, the proposed system improves the average repeatability to a 3.2%, over 13 times some reported data. The use of an ultra‐thin GC capillary column of 150 μm id performs better peak resolution in about 60% the time with usual 250 μm id capillary columns. The usefulness of this proposed optimised procedure has been proved in real air matrix samples, through a large study with the reliable characterisation of 93 different volatile compounds in the ambient air of a municipal solid waste treatment area     

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。     

Coupling pervaporation to AAS for inorganic and organic mercury determination. A new approach to speciation of Hg in environmental samples

The design and development of a new approach for Hg speciation in environmental samples is described in detail. This method, consisting of the coupling of pervaporation and atomic absorption spectrometry, is based on a membrane phenomenon that combines the evaporation of volatile analytes and their diffusion through a polymeric membrane. It is proposed here as an alternative to gas chromatography for speciation of inorganic and organic Hg compounds, as the latter compounds are volatile and can be separated by applying the principles mentioned above. The interest of this method lies in its easy handling, low cost, and rapidity for the analysis of liquid and solid samples. This method has been applied to Hg speciation in a compost sample provided by a waste water treatment plant.     

吹扫捕集–气相色谱–质谱法测定地表水中5种硝基苯类化合物

对吹地表水中5种硝基苯类化合物进行吹扫捕集富集,解吸后用气相色谱-质谱联用法同时测定,内标法定量,加入硫酸钠提高方法的灵敏度,优化并验证检测方法。实验结果表明,使用Te Kmer-Dohrmann 3100型吹扫捕集仪,在吹扫温度为45℃、吹扫14 min的条件下测定水质中5种硝基苯类化合物,在0~60μg/L范围内线性关系良好,检出限为0.03~0.05μg/L,加标回收率为91.7%~95.9%,测定结果的相对标准偏差为1.00%~1.84%(n=7)。该方法操作简便、准确度高、重现性好,能够满足地表水中5种硝基苯类化合物的同时测定。     

Comprehensive-trace level determination of methyltin compounds in aqueous samples by cryogenic purge-and-trap gas chromatography with flame photometric detection.

A comprehensive method was developed for the sensitive and fast determination of trace levels of methyltin compounds in aqueous samples. Tin compounds in aqueous solution at pH 5 were converted to the corresponding volatile hydrides: CH3SnH3, (CH3)2SnH2, and (CH3)3SnH, by reaction with potassium borohydride. A CP-4010 purge and trap injector (PTI) was used to purge analyte species from water directly. The volatile derivatives were base-line separated on a capillary column in an Angilent-6890 gas chromatograph by a suitable temperature program and were detected by a flame photometric detector (FPD). The detection limits were 18 ng L-1 for monomethyltin, 12 ng L-1 for dimethyltin, and 3 ng L-1 for trimethyltin, respectively. This method was successfully applied to the determination of methyltin compounds in different aqueous samples.