毛细管色谱切割-反吹法归一化分析汽油中芳烃

发展了一种毛细管色谱切割 反吹方法分析汽油中的芳烃。利用OV 2 3 3 0强极性毛细管预柱将芳烃保留至n C1 0 之后 ,并反吹到非极性毛细管柱中按沸点详细分离分析。从预柱先流出的组分和从分析柱流出的组分都先后进入同一检测器中 ,因此可用响应因子校正的归一化方法定量分析汽油中的芳烃。该方法在15min内完成汽油中苯至C1 0 芳烃的分析 ,结果的重复精度误差≤ 3 % (RSD) ,切割误差± 5s时对分析结果的影响≤ 4% (RSD)。对该方法的装置和部分应用进行了讨论     

毛细管气相色谱切割反吹技术归一化法定量分析航空煤油中的芳烃

用气相毛细管色谱切割反吹技术 ,和在FFAP毛细管预柱上芳烃比高它 3个碳数的烷烃之后出峰的特点 ,通过阀切换把芳烃反吹入非极性OV 1分析柱中 ,按照沸点进行分离。从预柱上先流出的组分和从分析柱上后流出的组分先后通过微型三通进入同一个FID检测器 ,因此可用校正响应因子归一化法进行定量分析。从预柱出口到检测器之间的阻尼柱阻力 6倍于分析柱阻力 ,反吹后因载气流速提高 5 .4倍而有效地压缩了谱带 ,提高芳烃等目标组分的检出灵敏度 2倍。通过切割反吹操作能很好地完成航空煤油中从苯到C11芳烃的检测 ,阀切换的可允许时间窗口达± 18s,且分析结果的重现性误差RSD≤ 4 .0 %。     

二维中心切割气相色谱法测定汽油中芳烃含量

利用二维中心切割气相色谱的原理和切换、反吹技术,将预柱(TCEP)中的待测组分切换到毛细管柱(SE-30)中,建立了汽油中苯、甲苯、C8和C8以上芳烃含量的检测方法。在第一次分析的进样状态下,在待测物质苯从预柱中流出之前,将六通阀切换到反吹状态,这样待测物质苯,甲苯等极性组分被切换至非极性的SE-30毛细管色谱柱中进行分析。在第二次分析的进样状态下,在乙苯流出之前立即将六通阀切换到反吹状态,TCEP柱中的保留组分进入分析柱中进行分析。采用氢火焰离子化检测器(FID),内标法定量,在检测范围内苯,甲苯,邻二甲苯,1,2,4-三甲苯线性关系良好,相关系数(r2)分别为0.9964,0.9981,0.9988和0.9989,对标样进行6次重复实验,相对标准偏差(RSD)都小于2%。     

气相色谱法测定汽油馏分中的单体芳烃

采用三柱一阀气相色谱系统单次进样、归一化法定量分析初馏至200 ℃的汽油(包括含有醇类、醚类的成品汽油)中的芳烃含量。具体操作:样品进入系统后分为两路,一路经过分析柱1(Col.2)后直接到检测器;另一路进入预切柱(Col.1),烷烃和烯烃先于芳烃流出,待烷烃和烯烃放空后将阀切换到反吹状态,Col.1中的芳烃被反吹出来,进入分析柱2(Col.3),经过分离后到检测器,经计算得到样品分析结果。该法简便、快速、样品用量少、测试范围宽,避免了汽油中其他组分对芳烃测定的干扰。     

二维气相色谱技术分析汽油中的3种酯类化合物

建立了一种采用填充柱切割-反吹二维气相色谱分析汽油中酯类化合物（包括乙酸乙酯、乙酸仲丁酯、碳酸二甲酯）的方法。利用非极性填充预柱将汽油中沸点低于正辛烷的轻组分保留进入分析柱,重组分反吹放空,轻组分和酯类化合物经一个装填有强极性固定相的色谱柱分离分析。采用外标法定量,3种酯类化合物在50~50000 mg/L范围内线性关系良好,相关系数（r²）分别为0.99999、1.00000和0.99995,标准样品6次重复性测定的相对标准偏差（RSD）均小于1.0%,回收率在98.7%~107.9%之间,方法检出限（S/N=3）为5 mg/L。该方法不需要进行样品前处理,具有操作简单,准确高效的特点,是汽油中酯类化合物测定的理想分析方法。     

油品族组成的详细分析和燃油中芳烃的分析

用毛细管液相色谱-毛细管气相色谱联用方法详细分析了航空煤油、各种柴油、润滑油、抽出油和塔底油的族组成。在毛细管液相色谱上分离得到的单环、双环、三环、四环和稠环芳烃族,经过多位存储接口后,顺序进入毛细管气相色谱,通过毛细管气相色谱对每个族组分作详细分析及定量。用单检测器的二维毛细管气相色谱切割-反吹方法定性定量分析汽油、航空煤油中的各种芳烃,从第一维柱流出的组分和第二维柱流出的组分都先后进入同一氢火焰离子化检测器中,因此能用质量校正响应因子归一化方法准确定量分析而不需要标准样。用上述技术分析实际样品,证明了     

二维气相色谱技术测定汽油中甲缩醛含量

提出了二维气相色谱技术测定汽油中甲缩醛含量的方法。利用非极性填充预柱将汽油中沸点大于正己烷的重组分反吹放空,轻组分和甲缩醛经一个装填有Carbowax-1500[15%(m/m)]固定相的色谱柱分离分析。甲缩醛的质量浓度在0.040~80.0g·L-1范围内与其峰面积呈线性关系,检出限(3S/N)为10mg·L-1。方法用于汽油样品的分析,加标回收率在102%~114%之间,测定值的相对标准偏差(n=6)在0.28%~0.91%之间。     

气相色谱法测定车用汽油中含氧化合物和苯胺类化合物

利用中心切割技术和双毛细管色谱柱系统,采用两次进样的方式,建立了气相色谱测定车用汽油中含氧化合物和苯胺类化合物的分析方法。第一次进样分析,组分首先进入非极性DB-1色谱柱(30 m×0.32 mm×1.0μm),按沸点由低到高的顺序分离,通过电磁阀切换将沸点小于2-己酮的组分切割至强极性GS-OxyPLOT色谱柱(10 m×0.53 mm×10μm)或CP-Lowox色谱柱(10 m×0.53 mm×10μm),其余重烃组分通过阻尼柱进入FID检测器。在GS-OxyPLOT或CP-Lowox色谱柱上,烃类组分与含氧化合物分离并进入检测器检测,消除了大量的烃类组分对含氧化合物测定的影响。第二次进样分析,设定电磁阀切换时间为间-甲基苯胺从非极性色谱柱流出的时间,苯胺类化合物在GS-OxyPLOT或CP-Lowox色谱柱上与烃类和含氧化合物分离并进入检测器检测。以乙二醇二甲基醚为内标化合物进行内标法定量。实现了在一套系统上同时测定车用汽油中添加的甲基叔丁基醚(MTBE)、甲醇、甲缩醛、乙酸仲丁酯、乙酸乙酯、苯胺、邻/间/对-甲基苯胺和N-甲基苯胺的含量,各组分的检测范围为0.01%~10%(质量分数),回收率为86.0%~102.6%。该法可以为车用汽油的质量控制提供有效的检测手段。     

溴加成脱烯反应用于含烯汽油单体烃及族组成的分析

 提出了一种用于汽油组成分析的新方法 ,该方法采用溴加成选择性地转化并检测烯烃 ,解决了单体烃分析中的烷烯混峰问题 ,简化了识谱过程 ,由此通过一个包含极性预柱与非极性分析柱的简单二维体系或者与气相仪 (GC)联用的原子发射光谱检测器 (AED)两种途径均可进行准确度高的单体烃分析。在所选溴加成条件下 ,汽油中烯烃溴化率为 10 0 % ,而烷烃和芳烃保持惰性。处理全过程仅需 12 0s～ 15 0s ,操作简单且重复性好。该处理适用于含烯量为 0～ 10 0 % (体积分数 )的汽油 ,且主要针对含烯较高的催化裂化汽油。     

高效可逆吸附测定含烯汽油族组成的气相色谱法研究

在研制成功高效烯烃可逆吸附剂ＡＤ－１的基础上,开发了一套适于日常分析的高稳定性专用ＳＯＡ分析系统和相应的分析方法。分析样品时,样品先进入极性分析柱（ＣＯＬ．１）,芳烃留在柱中,烯烃与烷烃继续进入可逆吸附柱（ＣＯＬ．２）。烯烃被吸附,烷烃进入检测器,待饱和烃全部流出后,切换十通阀反吹芳烃,待芳烃完全流出后再将十通阀切换回进样状态,同时将吸附柱升温至２００℃,使烯烃脱附出来,利用积分仪以面积归一法计算出样品中的饱和烃（Ｓ）、芳烃（Ａ）及烯烃（Ｏ）的含量。至此完成一次样品分析。     

Column switching-back flushing technique for the analysis of aromatic compounds in gasoline

A simple method, based on the technique of capillary column switching-back flushing, has been developed for the detailed analysis of aromatic compounds in gasoline. The sample was first separated on a 30-m long OV-2330 polar precolumn and then backflushed onto a nonpolar analytical column. The early eluting components from the precolumn and the components of interest (aromatic compounds plus heavier compounds) eluting from the analytical column are all directed to the same flame ionization detection system through a T piece, which permits the quantitative analysis of aromatic hydrocarbons in gasoline by a normalization method using correcting factors. The switching time window of the method is +/-5 s, resulting in easier operation and higher reliability. The reproducibility of the quantitative analysis was < or = 3% RSD for real gasoline samples.     

Preliminary experiments for the analysis of tetrahydrotetrols of benz[a]anthracene and benzo[a]pyrene derived from their hemoglobin adducts using a coupled-column high-performance liquid chromatographic system

Improved technologies for the detection of polycyclic aromatic hydrocarbon adducts are required for human biomonitoring. Therefore, a coupled-column high-performance liquid chromatographic method, with system-integrated sample processing, has been developed and its applicability for determination of tetrahydrotetrols of polycyclic aromatic hydrocarbons in acid hydrolysates of human hemoglobin has been investigated. A novel column-switching technique applying ‘thermotransfer’ is used to separate tetrahydrotetrols of benzo[a]pyrene and benz[a]anthracene more efficiently. Derivatives of polycyclic aromatic hydrocarbons from blood hydrolysates are concentrated on a pre-column and then transferred to the analytical column by applying an electrical current to heat the solvent eluting the pre-column. This method allows for rapid and quantitative transfer of the analytes from the pre-column to the analytical column, after HPLC-integrated sample processing.     

Determination of aromatic and polycyclic aromatic hydrocarbons in gasoline using programmed temperature vaporization-gas chromatography-mass spectrometry

A sensitive method is presented for the fast analysis of three aromatic and six polycyclic aromatic hydrocarbons (biphenyl, 3-methylbiphenyl, 4-methylbiphenyl, fluorene, phenanthrene, fluoranthene, pyrene, 1,2-benz(a)anthracene and chrysene) in gasoline samples. The applicability of a GC device equipped with a programmable temperature vaporizer (PTV) and an MS detector is explored. Additionally, a modular accelerated column heater (MACH) was used to control the temperature of the capillary gas chromatography column. This module can be heated and cooled very rapidly, making total analysis cycle times very short. The proposed method does not require any previous analyte extraction and preconcentration step, as in most methods described to date. Sample preparation is reduced to simply diluting the gasoline samples in methanol. This reduces the experimental errors associated with this step of the analytical process. By using sampling injection in the solvent vent mode, and through choice of a suitable temperature, the lightest major components of the gasoline were removed. Moreover, use of a liner packed with Tenax-TA allowed the compounds of interest to be retained during the process. This working strategy could be extended to other groups of compounds through the choice of different venting temperatures. In this way, a large part of the gasoline components are eliminated, the life of the liner is prolonged, and it is possible to inject sample volumes that will not saturate the chromatographic column. The limits of detection ranged from 0.61 microg/L (pyrene) to 6.1 microg/L (biphenyl), and precision (measured as the relative standard deviation) was equal to or lower than 7.3%. The method was applied to the determination of analytes in gasoline samples and the results obtained can be considered highly satisfactory.     

A trapping column for the coupling of reversed-phase liquid chromatography and capillary gas chromatography

A new technique for coupling reversed-phase liquid chromatography (RPLC) with gas chromatography is described. A fraction eluting from an RPLC column is trapped on a short column packed with polymeric adsorbent. After the mobile phase has been displaced with water, the analytes are desorbed with ethyl acetate. Following a delay time to enable the water to be flushed to waste, the ethyl acetate containing the analytes is introduced into the gas chromatograph under conditions suitable for partially concurrent solvent evaporation, i.e. below the solvent boiling point and at a rate just exceeding the evaporation rate. Post-column addition of water to the RPLC eluent helps to prevent breakthrough of compounds which are only modestly retained on the trapping column. The relationship between the capacity factors of the analytes on the trapping column and the required dilution factor is discussed. Polycyclic aromatic hydrocarbons are used as test compounds to study the system.     

Quantitative Determination of BTEX and Total Aromatic Compounds in Gasoline by Comprehensive Two-Dimensional Gas Chromatography (GC×GC)

Comprehensive two-dimensional gas chromatography (GC×GC) has been applied to the quantitative analysis of benzene, toluene, ethylbenzene, xylenes (BTEX), and all heavier aromatic compounds in gasoline. The two-dimensional chromatographic separation used volatility selection on the first-dimension column and polarity selection on the second-dimension column. In the resulting GC×GC chromatogram, aromatic species were resolved from other compound classes. Moreover, structurally related aromatics were grouped in a manner that facilitated identification and integration. The response of a flame ionization detector to each major aromatic group in gasoline was calibrated using internal standards. Quantitation produced results directly comparable with ASTM standard methods. The present GC×GC method can be expanded to analyze other gasoline components.     

Determination of trace hydroxyl polycyclic aromatic hydrocarbons in urine using graphene oxide incorporated monolith solid‐phase extraction coupled with LC‐MS/MS

The biomonitoring of hydroxy polycyclic aromatic hydrocarbons in urine, as a direct way to access multiple exposures to polycyclic aromatic hydrocarbons, has raised great concerns due to their increasing hazardous health effects on humans. Solid‐phase extraction is an effective and useful technique to preconcentrate trace analytes from biological samples. Here, we report a novel solid‐phase extraction method using a graphene oxide incorporated monolithic syringe for the determination of six hydroxy polycyclic aromatic hydrocarbons in urine coupled with liquid chromatography‐tandem mass spectrometry. The effect of graphene oxide amount, washing solvent, eluting solvent, and its volume on the extraction performance were investigated. The fabricated monoliths gave higher adsorption efficiency and capacity than the neat polymer monolith and commercial C₁₈ sorbent. Under the optimum conditions, the developed method provided the detection limits (S/N = 3) of 0.02–0.1 ng/mL and the linear ranges of 0.1–1500 ng/mL for six analytes in urine sample. The recoveries at three spiked levels ranged from 77.5 to 97.1%. Besides, the intra column‐to‐column (n = 3) and inter batch‐to‐batch (n = 3) precisions were ≤ 9.8%. The developed method was successfully applied for the determination of hydroxy polycyclic aromatic hydrocarbons in urine samples of coke oven workers.     

Enrichment and quantification of 18 polycyclic aromatic hydrocarbons from intermediates for plastics production by a generic liquid chromatography column switching

The polycyclic aromatic hydrocarbon concentration in plastic products is regulated in (European Union) No. 1272/2013. However, this only covers the end products and not intermediate substances. Therefore, a generic method was developed to analyze the polycyclic aromatic hydrocarbons listed by the Environmental Protection Agency and the European Union. This method is based on direct large volume injection from solutions of plastic additives followed by liquid chromatography coupled to fluorescence detection. The additives Irganox 1010, ureido methacrylate, and cetyl methacrylate 1618F were used as examples for method development. Two serially coupled columns allowed the matrix to be removed on the first column and the analytes to be separated on the second column. The columns were connected by an intermediate valve. The valve allowed the matrix to be diverted after the first column and water to be dosed upstream of the second column via an additional pump. This allowed samples in aqueous or organic media to be focused at the column head. An injection volume of 100 μl and online aqueous dilution of 1:3 led to a limit of detection below 1 ng/ml for 15 polycyclic aromatic hydrocarbons. Moreover, concentrations between 1.6 and 10.3 ng/ml were found in the three plastic additives.     

An improved method for determination of light hydrocarbons in stabilized crude oil

Summary This paper reports a quick, and simple method for quantitative determination of C₂ to C₆ hydrocarbons in stabilized crude oil without using a back flush system. A mixture of crude oil and internal standard is injected into a GC equipped with a 6 meter length of fused silica capillary as a guard column. The light hydrocarbons are separated individually up to the last peak of the hexane group with the heavier components trapped in the guard column. The total analysis time for each sample is 15 minutes. The base line is table for up to 15 consecutive analyses. The guard column and the injector port are then reconditioned by simply heating them for one hour at 300 °C.     

Estimation of Olefin Dimerisation Products by GC/GC–MS and IR Techniques

A GC and IR based protocol was developed for monitoring the isobutene dimerisation process wherein the complete characterisation of the products was carried out by GC coupled with mass spectrometry. In the dimerisation process, LPG from FCC process comprising a mixture of saturated and unsaturated C4 hydrocarbons is subjected to a dimerisation process using a catalyst to produce C8 hydrocarbons. The reaction is carried out keeping in view the demand for high-octane blending components in gasoline. The isooctene generated in the process (mainly from the dimerisation of isobutene) is converted into isooctane having the RON and MON value 100. The monitoring process requires the use of two different column chemistries, viz., a 100 m CPSIL PONA CB non-polar column for C8 and its isomers and an Alumina PLOT column for C4 hydrocarbons. A 100 m non-polar column does not separate the C4 mixture since the column is meant for gasoline range products containing C5 and above hydrocarbons. Therefore, a need was felt for an improvised method which can handle both the analyses simultaneously. A cryogenic oven program starting from 0 °C was developed for separating the isomers of C4 hydrocarbons and C8 hydrocarbons on a single column during the single run by Detailed Hydrocarbon Analyzer. The data obtained using the cryo programme was validated with data obtained using Alumina PLOT column on C4 mixture since the Alumina PLOT column is the widely accepted column chemistry for separating the C4 hydrocarbons. An IR method for the estimation of the total olefin content was developed using 2,2,4-trimethyl pentene-1 as the reference standard. The total olefins generated during the process were identified by GC–MS, quantified by DHA-FID and validated by infrared spectroscopy. A good correlation was found between GC and IR spectral results (correlation coefficient R ²  = 0.99).