SPE-HPLC法测定水中硝基苯酚类化合物

建立了以固相萃取为前处理条件,用液相色谱法测定水中10种硝基苯酚类化合物的分析方法。实验使用HLB(6 L/150 g)固相萃取柱富集水样中的目标化合物,二氯甲烷与乙酸乙酯体积比1:2的混合溶剂洗脱,采用Phenyl柱(4.6 mm×250 mm,5 μm)分离目标化合物,以乙腈(1%甲酸)/水(1%甲酸)为流动相进行梯度洗脱,二极管阵列检测器检测。10种硝基苯酚类物质在0.02~10 mg/L范围内呈现良好的线性。方法检出限为0.1~0.3 μg/L,水样加标相对标准偏差为5.19%~18.2%,平均加标回收率为49.8%~124%。该方法适用于水中10种硝基苯酚类化合物的测定。     

SPME-HPLC法测定废水中硝基苯酚类化合物

采用固相微萃取处理废水样,用高效液相色谱法测定水样中10种硝基苯酚类化合物。通过优化前处理和仪器测定的条件,使该方法在0.020 0 mg/L~3.00 mg/L范围内线性良好。方法检出限为5μg/L~39μg/L,空白水样的3个质量浓度水平加标回收率为49.3%~82.9%,RSD为8.3%~18.1%。用该方法测定某企业的实际废水样,结果未检出,其3个质量浓度水平加标回收率为50.6%~79.7%,RSD为7.6%~18.4%。     

液液萃取-气相色谱法测定水中硝基氯苯类化合物

建立了液液萃取-气相色谱法测定水中15种硝基氯苯类化合物的方法。中性条件下,在水样中加入氯化钠,用环己烷进行萃取,得到方法检出限为0.019~0.044μg/L,在10.0μg/L~1.0 mg/L范围内线性良好,相关系数均0.999。加标水平为2.5μg/L时,空白水样加标回收率为74.8%~104%,相对标准偏差为4.79%~11.5%;实际水样加标回收率为69.1%~111%,相对标准偏差为5.83%~17.6%。方法适用于成分不复杂的实际水样中硝基氯苯类化合物的检测。     

SPE-HPLC法测定固体废物浸出液中苯酚类物质

选择Agilent Bond Elut Plexa作为固相萃取柱,结合高效液相色谱测定固体废物浸出液中12种苯酚类化合物,通过试验优化条件,使目标物在0.100 mg/L~10.0 mg/L范围内线性良好,方法检出限在0.004μg/L~0.068μg/L之间,3个质量浓度水平加标回收率为78.0%~105%,测定6次结果的RSD为0.7%~5.0%。将该方法用于测定江苏省某工业园区污水处理企业5个废水处理污泥样品,结果 2,4,6-三氯苯酚和2,4-二硝基苯酚检出。     

顶空-气相色谱法测定地表水中6种乙酸酯类化合物

采用顶空-气相色谱法测定地表水中乙酸酯类化合物,并对顶空瓶的加热温度、平衡时间进行优化。优化后,方法在6种乙酸酯类化合物质量浓度0.05~1.00 mg/L范围内线性良好,检出限为4.49~58.5μg/L,RSD为0.61%~2.51%,加标回收率为96.5%~104%,方法便捷、环保、经济,适用于地表水中乙酸酯类的检测。     

GC和HPLC测定水中苦味酸的比较

建立了气相色谱法(GC)和高效液相色谱法(HPLC)测定水中苦味酸的分析方法,并对2种方法进行比较。GC法检出限为0.000 4 mg/L,线性范围为0.0~0.050 mg/L,加标回收率为92.3%~94.1%,相对标准偏差为4.6%~8.9%。HPLC法检出限为0.02 mg/L,线性范围为0.10~5.00 mg/L,加标回收率为93.7%~96.5%,相对标准偏差为1.3%~2.0%。2种方法相比,GC法灵敏度较高,可用于痕量分析,但操作烦琐,不能有效地将苦味酸与硝基酚类干扰物分离;而HPLC法虽然灵敏度较差些,但简单、快速、稳定性好、准确度高,可有效地将苦味酸与硝基酚类干扰物分离。     

水中硝基氯苯类化合物的应急检测方法研究

文章研究并建立了一种快速便捷测定水中硝基氯苯类化合物的方法。采用固相微萃取方法富集水中目标物,使用便携式气相色谱/质谱仪进行检测。优化后的萃取条件为:使用65μm的PDMS/DVB萃取头,水温60℃、转速200r/min下萃取50min。结果表明,硝基氯苯类化合物在10.0~500μg/L范围内呈现良好线性,相关系数均大于0.980;空白水样加标相对标准偏差为2.28%~11.3%,加标回收率为77%~130%;实际水样加标相对标准偏差为3.93%~6.73%,加标回收率为90%~115%;检出限范围为1.37~3.57μg/L。     

乙腈盐析萃取HPLC-PDA同时测定水中11种苯胺类化合物

通过对色谱分析和样品萃取条件的选择和优化，建立了同时分析水中11种苯胺类化合物的HPLC方法。样品经乙腈盐析萃取后直接进样分析，采用 ODS色谱柱，以乙腈-水为流动相进行梯度洗脱，用PDA检测。结果表明，11种苯胺类化合物在0.20~100mg/L范围内其浓度和检测信号呈良好的线性关系，方法检出限为0.002~0.007mg/L，地表水和废水样品加标回收率为81.6%~97.4%，相对标准偏差为1.5%~5.5%。     

加速溶剂萃取-液相色谱测定土壤中酞酸酯类化合物

建立了加速溶剂萃取-液相色谱法测定土壤中14种酞酸酯类化合物的方法。结果表明,该方法对14种酞酸酯分离度较好,加标回收率为67.1%~128%,精密度RSD(n=6)为5.2%~15.0%,方法检出限为0.021~0.034 mg/kg。该方法操作简便、准确,具有较好的实用性。     

气相色谱/质谱法测定水中15种酞酸酯类化合物

采用固相萃取-气相色谱/质谱法测定水中15种酞酸酯类化合物,确定方法的最优条件为:依次用10 m L正己烷和丙酮混合溶剂(V/V=5∶1)、甲醇和空白试剂水活化C18固相萃取柱后,水样以5 m L/min过柱萃取,再以8 m L正己烷:丙酮(V/V=5∶1)混合溶剂洗脱后,浓缩至1 m L,进气相色谱/质谱测定。该法的检出限为0.18~0.38μg/L,在0.50~20.0 mg/L范围内线性良好,相关系数均0.996。空白水样的加标回收率为71.8%~120%,相对标准偏差为1.73%~12.7%;实际废水水样的加标回收率为64.8%~135%,相对标准偏差为2.75%~18.0%。     

Assessment of priority phenolic compounds in sediments from an extremely polluted coastal wetland (Lake Maryut, Egypt)

Although high concentrations of trace organic pollutants were recorded along the Egyptian Mediterranean Coast and its corresponding coastal wetlands, no published data are available for the levels of phenolic compounds. Thus, this work aimed to investigate the levels of phenolic compounds in sediments of a heavily polluted coastal wetland (Lake Maryut, Egypt). For that purpose, a method was optimized for the extraction and detection of chlorophenols, methylphenols, and nitrophenols in sediments using GC-MS. Sediments were extracted with 0.1 M NaOH/methanol by sonication. Cleanup of sediment extracts using liquid–liquid extraction and SPE was found important to remove most of the interfering co-extracts. The proposed analytical methodology was validated by analysis of matrix spikes. Detection limits were 0.063–0.694 μg/kg dw for sediments. Good recoveries (70–110%) and precision values (RSD?<?20%) were obtained from the fortification experiments at the parts per billion level in sediments. The method was applied to investigate the level of contamination with phenols in 19 sediment samples from Lake Maryut. Results revealed that higher concentrations were observed in the main basin (MB) of Lake Maryut affected by the discharge of effluents from a primary wastewater treatment plant, direct discharge of industrial effluents, domestic wastes, and agricultural effluents from Qalaa Drain (QD). Chlorophenols (CPs) were the major group detected in the lake sediments followed by methylphenols (MPs) and nitrophenols (NPs). CPs were dominated by 2-, 4-, and 3-chlorophenols. Concentrations of CPs were higher at the north and northwestern parts of the MB indicating the influence of industrial effluents discharged into the lake. On the other hand, higher concentrations of NPs were observed at the south and southwestern parts of the MB, which is subjected to the discharge of agricultural and domestic effluents via QD. Results of the risk assessment revealed that phenol, cresols, 2,4-dinitrophenol, 4-NP, 2-CP, 2,3,4,6-tetrachlorophenol and 2,4-dimethylphenol are contaminants of concern and that adverse ecological effects could possibly occur to benthic species from the exposure to these pollutants in Lake Maryut and thus phenols should be included in monitoring and pollution prevention programs in the Egyptian aquatic environment affected by anthropogenic activities.     

苦味酸测定中关键问题的研究

目前测定苦味酸的国标方法为《生活饮用水标准检验方法有机物指标》(GB/T 5750.8—2006)中的衍生物-液液萃取-气相色谱法,在实际测试过程中,发现水样pH值和基质效应会影响苦味酸测定。当pH值为8~12时,生成的氯化苦响应强度变化不大;在pH约为13时,响应强度最大。水质中除腐殖酸、硝基甲烷及2,4,6-三硝基甲苯会影响苦味酸测定外,硝基酚类和甲基酚类同样起到正干扰作用,因此,国标方法不能全面和准确地测定水中的苦味酸含量。     

Simultaneous derivatization and extraction of nitrophenols in soil and rain samples using modified hollow-fiber liquid-phase microextraction followed by gas chromatography–mass spectrometry

A simple and sensitive method based on a modified hollow-fiber liquid-phase microextraction followed by gas chromatography–mass spectrometry has been successfully developed for the extraction and simultaneous derivatization of some nitrophenols (NPs) in soil and rain samples. Microwave-assisted solvent extraction was used for the extraction of NPs from the soil, while the rain sample was directly applied to the previously mentioned method. Briefly, in this method, the analytes were extracted from aqueous samples into a thin layer of organic solvent (dodecane?+?10 % tri-n-octylphosphine oxide) sustained in the pores of a porous hollow fiber. Then, they were back-extracted using a small volume of organic acceptor solution (25 μl; 10 mg/L N-methyl-N-(trimethylsilyl)trifluoroacetamide, as derivatization reagent, in acetonitrile) that was located inside the lumen of the hollow fiber. Under the optimized extraction conditions, enrichment factors of 255 to 280 and limits of detection of 0.1 to 0.2 μg/L (S/N?=?3) with dynamic linear ranges of 1–100 μg/L were obtained for the analytes. The accuracy of the approach was tested by the relative recovery experiments on spiked samples, with results ranging from 93 to 113 %. The method was shown to be rapid, cost-effective, and potentially interesting for screening purposes.     

Multi-component analysis of polar water pollutants using sequential solid-phase extraction followed by LC-ESI-MS

A multi-component screening analysis method for polar to medium-polar water pollutants was developed. Sample clean-up and group separation are performed by sequential solid-phase extraction (SSPE) using automated SPE with C18 and polymeric sorbent materials. Analyses are performed by liquid chromatography electrospray ionization mass spectrometry (LC-ESI-MS) using a single-quadrupole instrument. More than 90 priority compounds of environmental interest--comprising the most important chemical and substance classes: phenols, carboxylic acids, aromatic sulfonates, aromatic amines, pharmaceuticals, surfactants, dyes, and pesticides--have been chosen for the experiments. The compounds are divided by the SSPE procedure into 3 different polarity classes. The extraction recoveries were determined in the 3 fractions for every single substance, and were for most of the analytes in the range of 50-100%. A mixture of hexane-dichloromethane was used for the elution of nonpolar compounds like alkylphenols from C18. Methanol and acetone are well suited for the elution of more polar substances. The limits of detection (LODs) were determined for all compounds. Effluents from municipal and industrial wastewater treatment plants (WWTPs) treating waste water from textile industries; and the corresponding receiving waters (rivers and lakes) have been analysed with the developed method. Urban and industrial pollution was observed in rivers and streams in the area north of Milan, Italy. In the water samples different phenols (nitrophenols, bisphenol A, nonylphenol), alkylphenol ethoxylate surfactants, their metabolites with endocrine disrupting potential, aromatic sulfonates, linear alkylbenzenesulfonate surfactants, dyes, pesticides, pharmaceuticals, and a dichlorobenzidine compound were identified.     

铋磷钼蓝分光光度法测定土壤中磷含量

土壤中磷含量的分析是土壤环境监测的主要项目之一.建立了铋磷钼蓝分光光度法测定土壤中磷含量的新方法,与现有的《土壤全磷测定方法》(GB 9837-88)和土壤总磷快速检测仪方法进行了比较讨论.方法的检出限为5.0 mg/kg,对磷含量为475 mg/kg和292 mg/kg的标准土壤样品进行测定,结果与标准值吻合,其相对...     

便携式催化氧化-FID法测定固定污染源废气中非甲烷总烃

对便携式催化氧化-FID法测定非甲烷总烃的检出限、精密度、准确度、催化效率等性能指标开展研究,考察该方法测定固定污染源废气中非甲烷总烃的适用性。结果表明：催化氧化装置的转化效率为98.1%～99.7%,方法检出限为0.05 mg/m3（以碳计）;2个质量浓度水平的甲烷和丙烷混合标准气体测定结果的相对误差分别为-6.4%～6.1%、-4.7%～-0.5%,实验室内、实验室间测定结果的RSD分别为2.9%～5.9%和1.6%～2.5%、1.5%和0.6%。用该方法和国标法同时测定实际样品,两种方法测定结果的相对误差为6.4%～21.4%。     

一种便携式荧光测油仪在海上溢油应急监测中的适用性研究

研究了一种便携式荧光测油仪在海上溢油应急监测中的适用性,并与现行仲裁标准方法进行比较分析。研究表明:该便携式荧光测油仪测定海水中油类样品仅需100 mL水样,平均每个样品所需的前处理时间约340 s,方法检出限为0.003 mg/L,测定下限为0.012 mg/L。测定用标准物质配制的不同浓度海水样品,相对标准偏差为0.08%~0.87%,测定标准样品的相对误差为0.49%~4.50%,实际样品加标回收率为90%~107%。对标准物质配制的海水样品进行检测,与现行仲裁标准方法在0.05水平下无显著性差异。在渤海中部海上监测中,连续6 d测定不同标准样品的相对标准偏差为0.26%~0.83%。研究结果表明,该便携式荧光测油仪适用于现场对油类的定量分析和水质评价。     

水中总氮快速测定实验方法研究

针对现行总氮标准测定方法存在的操作繁琐、耗时长等缺点,采用COD消解加热器消解代替原标准方法中的高温高压消解步骤,以简化实验步骤、缩短用时,建立快速测定水中总氮的分析方法.通过对本方法进行平行实验、加标回收实验以及与标准方法的对比实验等分析实验结果,方法的线性范围为0 ～ 4.00 mg/L,平均加标回收率是102.3％,标样平行实验的相对标准偏差是1.05％,准确度、精确度和回收率均达到标准要求,方法具有一定的推广价值.     

机动车尾气排放检测方法对比分析

通过怠速、双怠速法对机动车尾气检测试验和数据对比分析表明,不同车龄段的电喷型轿车采用怠速法检测尾气达标率在73.3%～93.5%之间;双怠速法检测尾气达标率在40.0%～82.6%之间.不同车龄段的化油器型轿车采用怠速法检测尾气达标率在25.0%～57.1%之间;双怠速法检测尾气达标率在18.8%～57.1%之间.指出双怠速法对化油器车辆尾气控制同样有效果,双怠速法对筛选高污染车辆比怠速法更严格和科学.     

液液萃取-气相色谱-质谱法同时测定饮用水中的酞酸酯、百菌清和联苯胺

建立了液液萃取-气相色谱-质谱（LLE -GC/MS）同时测定饮用水中的6种酞酸酯类化合物、百菌清和联苯胺的方法。选用3种有机溶剂进行萃取，筛选出回收率高、操作简单的前处理方法，萃取后经气相色谱-质谱分析。方法表明：8种物质线性良好，相关系数为0．9978～0．9995，用二氯甲烷萃取回收率最佳，回收率在90．1％～118％之间，相对标准偏差在0．24％～7．21％之间。