深圳市大气中多环芳烃的污染特征与来源识别

利用大流量主动采样器于2009年12月~2010年1月及2010年6月,分冬季与夏季两批次对深圳市13个点位进行大气样品采集,检测其气相及颗粒相中总的多环芳烃(PAHs)浓度.结果表明,冬季深圳市大气中总PAHs的浓度为17.9~92.3ng/m3,平均值为45.3ng/m3;夏季总PAHs浓度范围为8.64~96.3ng/m3,平均值为32.2ng/m3.两个季节PAHs单体中均以3~4环为主,占总浓度的75%以上;单个组分与总量的相关性分析表明,夏季明显优于冬季.来源分析表明,冬季大气中PAHs来源比夏季更为复杂,通过特征分子比值法推断冬季PAHs主要来源于石油源、燃煤、机动车尾气排放;夏季主要来源于机动车尾气排放.利用毒性当量因子法和致癌风险评价其污染水平和毒性风险,结果表明深圳市大气中PAHs污染与国内部分城市相比,处于较低水平.     

长江武汉段沉积物再悬浮过程中PAHs释放的预测模型

为研究长江武汉段沉积物再悬浮过程中多环芳烃的释放,采用回归方法建立了剪应力与再悬浮颗粒物浓度、有机碳含量及PAHs浓度之间的定量关系模型,并结合PAHs在悬浮颗粒物-水体分配系数,建立了不同剪应力条件下再悬浮过程中上覆水体PAHs浓度预测模型,通过模型预测结果与实验结果的比较,表明模型具有良好的预测效果,可用来进行不同剪应力条件下沉积物再悬浮过程PAHs释放的预测.     

Predicting the acute lethality of a chlorinated benzene mixture in soils: a comparison of solid-phase microextraction,body residue,and solvent extraction techniques

When predicting the adverse effect(s) of chemical pollution on an exposed organism, a measurement of body residue is often considered a more accurate estimate of dose than those estimates derived from a solvent extraction or solid-phase microextraction of the polluted exposure medium. The magnitude of this perceived difference in accuracy, and thus the accuracy of the corresponding toxicity prediction, were investigated in the present two-phase study. In Phase I, an acute lethality response was correlated with dose estimates derived from body residue, solvent extraction, and SPME. In Phase II, acute lethality was predicted from Phase I data. The accuracy of Phase II toxicity predictions was determined by comparing predicted mortality to observed mortality. Although this study revealed that body residue indeed provided the most accurate prediction of toxicity, the margin of this comparatively greater accuracy suggests that alternative methods may provide equally viable dose estimates and, subsequently, equally viable toxicity predictions.     

Polycyclic aromatic hydrocarbons in medicinal plants from Syria

The levels of 16 US Environmental Protection Agency polycyclic aromatic hydrocarbons (EPA PAHs) in 10 medicinal plants in different used parts of plant (leaves and flowers) have been determined. The analytical method consists of sample preparation by ultrasonic extraction with dichloromethane followed by silica gel clean-up. Subsequently, the analysis was carried out by reversed-phase high-performance liquid chromatography (HPLC) coupled to both ultraviolet and fluorescence detections in series to insure the detection of all 16 EPA PAHs. It was observed that the sum of the 16 PAHs (ΣPAHs) in the investigated medicinal plants ranged from 47 to 890 μg kg^–1 where the highest ΣPAHs was found in Sage plant sample. Light PAHs were dominants in all studied medicinal plants. The sum of eight genotoxic PAHs (ΣPAH8) have shown a better indicator of the degree of contamination with carcinogenic PAHs compared to benzo[a]pyrene in these products.     

Possibilities and limitations of ecotoxicological testing of chemicals

This study concerns the polycyclic aromatic hydrocarbons (PAH's) emission from gasoline and diesel automobile engines.

The sampling procedure, the extraction and the analytical method are presented. Using the gas chromatography‐mass spectrometry technique it is possible to detect and quantify easily about 15 PAH's. Data obtained on exhaust particles collected from gasoline and diesel automobile engines are presented and discussed.     

Gas chromatographic studies of chlorinated phenols,chlorinated anisoles,and chlorinated phenylacetates

The g.l.c. retention times of all chlorinated phenols, anisoles, and phenylacetates on different capillary columns are presented. The relative retention times of the chlorinated phenols are discussed with reference to their pK_a values and their toxicities.     

Project tocoen. The fate of selected organic pollutants in the environment—iv. soil,earthworms and vegetation 1988

The samples of soils, earthworms and vegetation (needles, lichens, mosses) were collected for the realization of Project TOCOEN (Toxic Organic Compounds in the ENvironment). The samples were collected from three TOCOEN model areas in Czechoslovakia—one city and two rural areas. The samples were analyzed for polycyclic aromatic hydrocarbons (PAHs), chlorinated pesticides (C1‐PEST) and polychlorinated biphenyls (PCBs).     

Pah characteristics in ambient air within a steel industrial complex

Ambient air samples at ten sites in an iron and steel industrial complex were collected from June to December for analyzing polycyclic aromatic hydrocarbons (PAHs). Sixteen species of PAH components in air samples were identified. The results indicate that both gaseous phase and particle‐bound PAHs at the top of the cokemaking plants are unusually high. The profiles of particle‐bound PAHs indicate that the predominant species at the top of, the coke oven batteries are those of high molecular weight components. The major components of particle‐bound PAHs at sampling sites near the fenceline, however, include the medium molecular weight components. The PAH profiles of air samples within the industrial complex show a strong similarity to those of cokemaking plant samples. The concentrations and the specific content of benzo(a)pyrene in the iron and steel industrial complex are higher than those values measured in urban area, petrochemical industry park, and open‐air burning area.     

太原市工、商业区PM10中PAHs碳同位素组成及来源

利用中流量大气综合采样仪采集太原市工业区和商业区PM₁₀样品,使用GC/IRMS技术分析了PAHs的δ13C值(碳同位素组成),并根据碳同位素质量平衡计算了煤烟尘和机动车尾气对2类功能区的贡献率. 结果表明:工业区PM₁₀中PAHs的δ13C值在-26.0‰~-24.5‰之间,随环数增加呈贫13C趋势,与煤烟尘δ13C值的变化趋势一致,表明煤烟尘是工业区的一个主要污染源;商业区PAHs的δ13C值在-26.6‰~-26.2‰之间,较工业区显著贫13C,商业区与工业区的污染源有明显差异;除机动车尾气和煤烟尘外,工业区和商业区还有其他污染源输入,其中工业区有生物质燃烧排放输入,商业区有机动车曲轴箱润滑油残渣输入;煤烟尘和生物质燃烧对工业区的贡献率分别为59.3%~70.8%和29.2%~40.7%,表明工业区煤烟污染严重;机动车对商业区PAHs的贡献率在86.1%~95.8%之间,是商业区PM₁₀中PAHs的主要排放源,其中润滑油残渣的贡献率(在40.9%~85.3%之间)最大,机动车尾气的贡献率在8.3%~54.9%范围内,而煤烟尘的贡献率(在4.2%~13.9%之间)最小.      

滴水湖水系沉积物中多环芳烃的分布及风险评价

2012年,每两个月采集一次上海人工滩涂湖泊——滴水湖水系表层沉积物,检测16种多环芳烃(PAHs)含量.结果表明,滴水湖水系∑PAHs变化范围为74.03~579.20ng/g,平均值为272.55ng/g.其中,闸外引水河[(407.64±6.90)ng/g]≈闸内引水河[(427.99±213.84)ng/g]>滴水湖[(156.33±62.00)ng/g].研究区各点蒽/(蒽+菲)比值均大于0.1,说明PAHs主要来自于石油燃烧源.生态风险评价表明,滴水湖水系沉积物PAHs不存在严重的生态风险,但闸外和闸内引水河沉积物PAHs存在较低几率的潜在风险,湖区沉积物PAHs则无潜在风险.