徐州市区不同季节大气TSP和PM10中PAHs污染特征及健康风险评估

于2009年2月-8月利用高效液相色谱法对徐州市区冬、春、夏3个季节大气TSP和PM10中16种多环芳烃进行分析,结果表明：大气TSP和PM10中∑PAHs不同季节分布规律均为：冬季〉春季〉夏季;冬季,荧蒽污染浓度最高;春季和夏季苯并（g,h,i）芘浓度最高;不同环数PAHs春季和年均值呈规律均为：6环〉4环〉5环〉3环〉2环;夏季为：6环〉5环〉4环〉3环〉2环;冬季为：4环〉5环〉6环〉3环〉2环;大气TSP中整体苯并（a）芘等效致癌毒性（BEQ）不同季节分布规律为：冬季（4.517ng/m3）〉夏季（1.602ng/m3）〉春季（1.413ng/m3）;PM10中整体BEQ不同季节分布规律为：冬季（3.706ng/m3）〉春季（1.504ng/m3）〉夏季（1.331ng/m3）;采暖期大气颗粒物中PAHs污染对人体健康危害风险相对较高。     

北京地区表层土壤中多环芳烃的分布特征及污染源分析

根据北京地区不同环境功能区62个样品的分析结果,讨论了研究区表层土壤中多环芳烃的分布特征及污染源类型。结果表明：（1）研究区表层土壤中检测到的多环芳烃主要包括萘、苊、菲、惹烯、三芴、荧蒽、芘、、苯并蒽、苯并[b]荧蒽、苯并[k]荧蒽、苯并[e]芘、苯并[a]芘、苝、二苯并[a,h]蒽、茚并[1,2,3–cd]芘、苯并[g,h,i]苝及其同系物;（2）不同环境功能区表层土壤中多环芳烃的组成及质量分数均存在一定的差别,16种优先控制的多环芳烃质量分数为175.1~10 344 ng.g-1,其中城市中心区表层土壤中多环芳烃的质量分数最高,交通干线附近、工矿企业附近表层土壤中PAHs的质量分数较高,林地、果园和农田表层土壤中PAHs的质量分数较低;（3）表层土壤中PAHs既有来源于石油源,也有来源于化石燃料燃烧产物的,但不同功能区二者贡献存在差别,其中农业用地（林地、果园、农田）中PAHs主要来源于石油源（或部分来源于土壤母岩中的有机质）,城区、交通干线附近及工矿企业附近表层土壤中PAHs污染源以化石燃料燃烧产物输入为主。     

青岛地区大气气溶胶中多环芳烃的GC/MS分析

本文采集了青岛5个区的大气气溶胶样品，参照美国EPA610方法，用GC/MS分析鉴定多环芳烃。结果表明，青岛市大气气溶胶中PAHs总量的总趋势是东部高于西部，中部高于南、北部。多环芳烃的环数分布表明，气溶胶中PAHs几乎全部由人类活动产生。16种优先控制多环芳烃化合物中的萘、苊、芴、荧蕙、茚并[1，2，3-cd]芘，苯并[b]荧蒽、苯并[k]荧蒽等有毒有害有机污染物普遍检出于市内五区。苯并[a]芘的大气含量甚微。     

钢铁工业区周边农业土壤中多环芳烃(PAHs)残留及评价

对某大型矿业企业周边农业土壤中多环芳烃(PAHs)残留量进行了调查。结果表明,PAHs总残留量范围为312. 2~27 580. 9ng·g-1,且以4环以上多环芳烃组分为主。所有土样中均检出PAHs,单一污染物以芘、艹屈、荧蒽、苯并[a]芘、蒽、菲、苯并[a]蒽、苯并[k]荧蒽、茚并[1,2,3 cd]芘、苯并[g,h,i]苝为主。PAHs残留量与有机质含量相关性较好。不同样区土壤PAHs残留量受常年风向影响明显。以加拿大农业区域土壤PAHs的治理标准值为指标,用内梅罗综合指数法进行评价表明,研究区农业土壤达重污染水平的占37%,中度污染的占19%,轻污染的占25%,另有13%的采样点污染程度处于警戒限,仅有6%的采样点尚处于安全级。     

云南宣威肺癌高发区C1煤燃烧排放颗粒物中PAHs的组成特征及健康风险

宣威煤燃烧排放产物与其所导致的肺癌高发率一直是国际学术界关注的热点,但煤燃烧排放颗粒物中的关键致毒组分还不清楚。以肺癌高发区产出的晚二叠世C1煤燃烧排放不同粒径颗粒物为研究对象,分析其中主要有害有机污染物多环芳烃(PAHs)的分布特征及其健康风险。结果表明宣威煤燃烧排放的颗粒物中16种PAHs的总质量浓度为77 359.21 ng·m-3,其中含量最高的是苯并(g,h,i)苝,其他主要的PAHs依此为:屈、苯并(b)荧蒽、苯并(a)蒽、荧蒽、二苯并(a,h)蒽、菲、苯并(k)荧蒽、茚并(1,2,3-cd)芘;强致癌化合物苯并a芘(Ba P)总浓度亦可达到10 060.13 ng·m-3;这些有害有机物主要分布在细颗粒物中;不同粒径颗粒物的毒性当量存在明显差异,细颗粒的毒性当量占可吸入颗粒物中PAHs总毒性当量的87.4%,远高于粗颗粒(12%)和超细颗粒物(0.4%)的毒性当量。     

高铁酸钾降解荧蒽和苯并[a]芘的偏振荧光光谱研究

考察了高铁酸钾对荧蒽和苯并[a]芘两种PAHs(多环芳烃)的降解反应过程,并应用偏振荧光光谱技术研究了荧蒽和苯并[a]芘两种PAHsr降解体系反应过程及其差别的识别,着重探讨了两种PAHs降解体系反应过程中的多种荧光波长模式与偏振度、三维荧光(EEM)与偏振三维荧光(PEEM)变化规律,最后由时间扫描荧光模式直接获得反应动力学拟合方程式.实验结果表明,各荧光识别模式一致地显示出高铁酸钾对荧蒽和苯并[a]芘的显著性降解作用及其对应的各荧光强度变化规律,即反应时间大于40 s后,两种PAHs(多环芳烃)的降解反应均不明显,且降解过程中均无新的荧光发色团结构生成.在高铁酸钾与荧蒽/苯并[a]芘摩尔比为1∶1、1∶4、4∶1的各降解体系的反应过程均符合一级反应动力学规律.荧蒽降解曲线的线性关系更高,苯并芘降解速率更快,多种荧光光谱相结合能够实现对PAHs的降解过程的便捷而有效的追踪,其揭示的结果与分子机理一致,即苯并[a]芘分子较荧蒽分子具有更大的π电子密度,因而在Fe(Ⅵ)夺电子过程中,更易于失去电子而被Fe(Ⅵ)氧化降解.     

呼和浩特市冬季PM_(10)中多环芳烃的污染特征及来源解析

2013年12月在呼和浩特市主城区9个环境空气监测点位同步采集PM_(10)样品,对PM_(10)浓度和16种多环芳烃的浓度、污染特征进行了分析,使用特征比值和主成分分析对多环芳烃来源进行了解析.9个监测点位的PM_(10)浓度介于23.5—322μg·m-3之间,16种多环芳烃总量介于5.34—850 ng·m-3之间.荧蒽、芘、苯并[a]蒽、、苯并[b]荧蒽、苯并[a]芘、苯并[g,h,i]苝和茚并[1,2,3-cd]芘等多环芳烃单体浓度较高,这8种多环芳烃占多环芳烃总浓度的80.4%.主成分分析所获得污染源结果和特征比值法定性判断出的污染源结果一致,燃烧源、机动车尾气源和石油源为主要污染源,分别贡献61.3%、16.0%和10.4%.     

东江流域农村土壤中多环芳烃的分布特征及其健康风险评估

为了解东江流域农村土壤多环芳烃的分布特征与人类健康风险,采集了30个不同土地利用类型农村表层土壤样品,进行采用索氏抽提法,硅胶/氧化铝（2：1）层析柱分离纯化,最后加内标经气相色谱-质谱仪定量解析的方法测定16种多环芳烃的含量。同时,测定了土壤中不同形态有机质包括总有机碳（TOC）、非水解性有机碳（NHC）、黑碳（BC）以及无定形有机碳（AOC）的含量。结果表明,土壤多环芳烃质量分数在24-238μg·kg-1之间,平均质量分数为107±60μg·kg-1。在16种多环芳烃中,萘、菲、荧蒽和苯并（b）荧蒽的含量最高,占总多环芳烃含量的比重依次为16%、20%、10%和10%。土壤中多环芳烃含量与TOC、NHC以及BC均具有极显著的线性关系（p〈0.01）,三者斜率的大小顺序为BC〉NHC〉TOC（p〈0.01）,表明土壤有机碳中的非水解性有机碳和黑碳在控制土壤中多环芳烃的分布、积累中发挥着重要的作用。土壤中多环芳烃含量与AOC的相关性不显著（p=0.29）。另外,健康风险评价表明儿童暴露的增量终身致癌风险（ILCRs）在可接受的安全范围内（ILCRs 〈10-6）,而成人暴露的增量终身致癌风险则相对较高（10-6皮肤接触〉呼吸;而成人则为：皮肤接触〉误食土壤〉呼吸。     

淮河流域安徽段水系沉积物中多环芳烃的污染性状研究

应用气相色谱质谱联用仪测定淮河流域安徽段水系沉积物样品中萘、二氢苊、苊、芴、菲、蒽、荧蒽、芘、苯并[a]蒽、、苯并[a]芘和二苯并[a,h]蒽等12种多环芳烃的质量分数,并在此基础上分析沉积物中多环芳烃的区域分布、污染特征和来源。结果表明：研究区水系沉积物中多环芳烃有一定程度的富集,但与国内其他河流相比,样品中多环芳烃的质量分数不高;淮河南北岸支流沉积物中多环芳烃的含量差异比较明显,尤其是东淝河,含量明显低于淮北平原上的其它河流;淮河主干道和北岸支流沉积物中4环以上的多环芳烃含量较高,而南岸支流的淠河和东淝河沉积物中2～3环的多环芳烃平均含量明显高于其他环数;通过污染来源分析,沉积物中多环芳烃除与天然成岩过程有关外,大都是由有机物质的燃烧与热解引起的。     

杭州市郊区表层土壤中多环芳烃的风险分析

采集杭州市郊区表层土壤中多环芳烃的样品,用色谱-质谱技术对多环芳烃化合物进行定量分析。美国环保总署推荐优先控制的16种多环芳烃单体质量分数在1.49～87.43 ng.g-1之间,萘、芴、苊等低分子量芳烃质量分数相对较低;、茚并[1,2,3-cd]芘、苯并[ghi]苝等高分子量芳烃质量分数相对较高,其中苯并[ghi]苝质量分数最高。对照荷兰的土壤标准,杭州市郊区表层土壤中的荧蒽、、茚并[1,2,3-cd]芘、苯并[ghi]苝超标比较严重,超标率100%;多环芳烃的Bap等效毒性当量是荷兰规定目标值的2倍;因此,杭州市郊区表层土壤中存在一定的潜在风险。多环芳烃Ant/（Phe＋Ant）、BaA/（Chr＋BaA）、Flua/（Pyr＋Flua）等参数表明,多环芳烃主要来源于燃烧源,且以机动车尾气为主;BeP/（BeP＋BaP）比值偏高,可能与土壤中的多环芳烃主要来源于大气沉降有关。     

珠江水体表层沉积物中PAHs的含量与来源研究

沿珠江白鹅潭水域及大学城官州河流域设立6个采样点,利用沉积物捕获器收集沉积物。参照美国EPA8000系列方法及质量保证和质量控制,对各采样点表层沉积物中16种多环芳烃（polycyclic aromatic hydrocarbons,PAHs）进行分析,以阐明珠江广州河段表层沉积物中PAHs的含量和分布特征,并结合特征化合物指数对其来源作初步探讨。珠江广州河段表层沉积物中PAHs总量介于4 787.5～8 665 ng·g^-1,平均值为7 078 ng·g^-1,黄沙码头河涌出口沉积物中总量为最高（8 665 ng·g^-1）,芳村码头为最低（4 787.5 ng·g^-1）。16种多环芳烃中菲、荧蒽、芘含量较高,分别占PAHs总量的16.11%、14.47%和17.77%。特征化合物荧蒽/202比值均小于0.5,茚并[1,2,3-cd]芘/276比值均大于0.2,表明珠江广州段表层沉积物中PAHs主要来源于化石燃料的不完全燃烧。     

Monitoring of environmental exposure to polycyclic aromatic hydrocarbons: a review

Polycyclic aromatic hydrocarbons (PAHs) are a large group of organic compounds with two or more fused aromatic rings. They have a relatively low solubility in water, but are highly lipophilic. Most of the PAHs with low vapour pressure in the air are adsorbed on particles. When dissolved in water or adsorbed on particulate matter, PAHs can undergo photodecomposition when exposed to ultraviolet light from solar radiation. In the atmosphere, PAHs can react with pollutants such as ozone, nitrogen oxides and sulfur dioxide, yielding diones, nitro- and dinitro-PAHs, and sulfonic acids, respectively. PAHs may also be degraded by some microorganisms in the soil. PAHs are widespread environmental contaminants resulting from incomplete combustion of organic materials. The occurrence is largely a result of anthropogenic emissions such as fossil fuel-burning, motor vehicle, waste incinerator, oil refining, coke and asphalt production, and aluminum production, etc. PAHs have received increased attention in recent years in air pollution studies because some of these compounds are highly carcinogenic or mutagenic. Eight PAHs (Car-PAHs) typically considered as possible carcinogens are: benzo(a)anthracene, chrysene, benzo(b)fluoranthene, benzo(k)fluoranthene, benzo(a)pyrene (B(a)P), dibenzo(a,h)anthracene, indeno(1,2,3-cd)pyrene and benzo(g,h,i)perylene. In particular, benzo(a)pyrene has been identified as being highly carcinogenic. The US Environmental Protection Agency (EPA) has promulgated 16 unsubstituted PAHs (EPA-PAH) as priority pollutants. Thus, exposure assessments of PAHs in the developing world are important. The scope of this review will be to give an overview of PAH concentrations in various environmental samples and to discuss the advantages and limitations of applying these parameters in the assessment of environmental risks in ecosystems and human health. As it well known, there is an increasing trend to use the behavior of pollutants (i.e. bioaccumulation) as well as pollution-induced biological and biochemical effects on human organisms to evaluate or predict the impact of chemicals on ecosystems. Emphasis in this review will, therefore, be placed on the use of bioaccumulation and biomarker responses in air, soil, water and food, as monitoring tools for the assessment of the risks and hazards of PAH concentrations for the ecosystem, as well as on its limitations.     

Polycyclic aromatic hydrocarbons in soils around Guanting Reservoir,Beijing, China

The concentrations of 16 polycyclic aromatic hydrocarbons (∑ 16PAHs) were measured by gas chromatography equipped with a mass spectrometry detector (GC-MS) in 56 topsoil samples around Guanting Reservior (GTR), which is an important water source for Beijing. Low to medium levels of PAH contamination (mean=394.2±580.7 ng g^?1 dry weight (d.w.)) was evident throughout the region. In addition, localised areas of high PAH contamination near steel and cement factories were identified, with ∑ 16PAHs concentrations as high as 4110 ng/g, dry weight (d.w.). There was a significant positive correlation (r²=0.570, p<0.01) between total organic carbon content and ∑ 16PAHs concentrations. Phenanthrene was the predominant compound, accounting for 27.2% of the ∑ PAH concentration, followed by chrysene>pyrene>benzo[a]anthracene≈ benzo[b]fluoranthene≈ benzo[a]pyrene. Four-ring PAH homologues (39%) were dominant. The higher proportion of 4–6 ring homologues, molecular indices, and the spatial distribution of PAH indicated that industrial discharges, incineration of wastes and traffic discharges were the major sources of soil PAHs around the water reservoir.     

Dependency of polycyclic aromatic hydrocarbon concentrations on particle size distribution in Tehran atmosphere

In this work, the airborne particulate matter with an aerodynamic diameter less than 10 µm (PM₁₀) was fractionated in a six-stage high-volume cascade impactor to identify particulate size distribution in Tehran atmosphere. The study was conducted at 15 sites located in the north, south, east, west, and central parts of Tehran in 2005. Air samples were analyzed for 16 polycyclic aromatic hydrocarbons (PAHs) by HPLC. The daily PM₁₀ concentrations at the peak of traffic in roadside areas were found to be 106–560 µg m^?3. The cumulated concentration sum of PAHs, based on 16 species, was found to have an average concentration of 380 ng m^?3. Furthermore, it was found that more than 60% of PAHs belonged to the small particulate size range, having sizes of less than 0.49 µm, some containing benzo(ghi)perylene and indeno(123cd)pyrene (high molecular weight) with average concentrations of 8 and 6 ng m^?3 and fluorene, phenanthrene, and fluoranthene (low molecular weight) with average concentrations of 14, 13, and 19 ng m^?3, respectively. In addition, the results revealed that the lighter three- and four-ring PAH compounds were the most abundant pollutants in the air collected at all the sampling sites.     

Polycyclic aromatic hydrocarbons in Syrian olive oils and their likely daily intakes

The levels of 16 US Environmental Protection Agency polycyclic aromatic hydrocarbons (16 EPA PAHs) in Syrian olive oils have been determined. Forty-two samples including commercial extra virgin and virgin olive oils, and virgin olive oils from olive mills were analyzed. Only naphthalene (NAP) was detected in all olive oil samples under investigation. Among the studied 16 EPA PAHs, the highest maximum concentration was also observed for NAP (120 μg kg^?1). Moreover, three samples exceeded the European Union (EU) maximum level of 2 μg kg^?1 for benzo[a]pyrene (BaP) in oils and fats, and only one sample exceeded the EU maximum level of 10 μg kg^?1 for the sum of benz[a]anthracene, chrysene, BaP, and benzo[b]fluoranthene (PAH4). The likely daily intakes of the total sum of 16 EPA PAHs, the sum of eight genotoxic PAHs, the sum of PAH4, the BaP, and the BaP equivalent through consumption of Syrian olive oils were estimated.     

重金属和多环芳烃复合污染对土壤酶活性的影响及定量表征

以土壤脲酶和脱氢酶为探针物质，室内培养条件下较为系统地研究了重金属（Cd、Zn、Pb）和多环芳烃（菲、荧蒽、苯并a芘）复合污染对土壤酶活性的影响及其定量表征、结果表明，复合投加上述污染物能使土壤酶活性受到不同程度的抑制，其中，脱氢酶最为敏感，其活性是表征重金属和多环芳烃复合污染的一项重要的参考指标．对复合污染模型的建立与分析表明，土壤环境中，重金属和多环芳烃复合污染的类型和强度与污染物的浓度和复合污染时间密切相关．影响土壤脲酶活性的主要因子依次为：Cd〉Zn与苯并a芘的交互作用〉Zn〉Pb〉Zn和菲的交互作用，影响土壤脱氢酶活性的主要因子依次为：Cd和Zn的交互作用〉Cd〉Zn〉苯并a芘〉Cd和菲的交互作用，其中，Zn和苯并a芘相互作用对脲酶活性以及Cd和Zn交互作用对脱氢酶活性的影响均表现为拮抗作用，Zn和菲，Cd和菲之间的交互作用，无论是对脲酶还是脱氢酶均表现为协同作用，图1表3参18     

Concentration of some polycyclic aromatic hydrocarbons in rain,soil and ground water around Ismailia,Egypt

Residues of acenaphthylene, fluorene, anthracene, pyrene, chrysene, benzo(b)fluoranthene and benzo(k)fluoranthene were monitored in rain, soil and groundwater around Ismailia, in northeast Egypt. Residues detected in rain water in 1995 and 1996 were mainly of relatively low molecular weight. Both acenaphthylene and fluorene were detected in rain for the two consecutive years. Top soil has shown a wider spectrum and higher concentrations of (PAHs) than those detected in deep soil, rain and ground water. Only three compounds, acenaphthylene, fluorene and anthracene were detected in samples collected at 50 cm depth. While no traces of PAHs were detected at 1 m depth detectable concentrations of fluorene and anthracene were monitored in groundwater.     

徐州市城市大气中的PAHs来源解析

采用化学质量平衡模型（CMB）对徐州市大气颗粒物中的多环芳烃（PAHs）进行来源分析,从而来确定各个源对大气的PAHs贡献值。主要通过利用大流量采样器配置PM10切割头在冬季和夏季对不同功能区,即生活区、工业区和旅游区采样大气中的可吸入颗粒物（PM10）样品,并用高效液相色谱法（HPLC）重点分析和研究了美国环保局（EPA）列出的16种PHAS优先污染物。研究结果表明：徐州市PM10污染比较严重,PM10污染质量浓度水平冬季是（288.81μg·m-3）大于夏季（276.34μg·m-3）,特别是工业区,污染数值达到393.13μg·m-3。夏季的总PAHs质量浓度为22.89 ng·m-3,分别是生活区28.35 ng·m-3、工业区21.75 ng·m-3和旅游区18.58 ng·m-3。冬季的总PAHs质量浓度为306.29 ng·m-3,分别是工业区388.03 ng·m-3、生活区276.29 ng·m-3和旅游区254.28 ng·m-3。夏季和冬季情况下,旅游区的污染相对来说都是最低的PM10中多环芳烃的源解析结果为,煤烟尘污染源的全年贡献率为64.00%,冬季煤烟尘污染源的贡献率为66.51%,夏季煤烟尘污染源的贡献率为57.21%,说明煤烟尘是PM10中多环芳烃的主要贡献源,土壤尘次之,全年贡献率为24.90%,冬季为25.48%,夏季为28.97%,因此,扬尘和烟煤尘的污染是徐州市的PM10中PAHs的最主要来源。