典型岩溶区多介质中多环芳烃的环境存在特征

选择典型岩溶地区广西大石围天坑群为研究对象,采用2007—2008年同期采集的大气干湿沉降、空气、土壤、地下河水和沉积物样品测试数据,运用16种多环芳烃（PAHs)的成分谱、分布特征和特征比值,结合其物理化学性质进行对比分析。初步研究结果表明,全年大气干湿物/土壤/地下河沉积物均以屈（Chr）、苯并\[b]荧蒽（BbF）、苯并\[k]荧蒽（BkF）、苯并\[a]芘（BaP）4种4～6环PAHs为主;同期天坑空气/秋冬季干湿沉降物/地下河水以萘（Nap）、芴（Flu）、菲（Phe）和蒽（Ant）4种2～3环PAHs为主;各组介质中的PAHs存在特征具有较好的一致性,但也有一定的差异。利用这种方法初步解释了岩溶地区土壤、地下河水和沉积物中PAHs污染的来源（或输入）;同时证明了大气干湿沉降物是偏远岩溶地区土壤和地下河中PAHs的主要来源。因此建议在污染源调查过程中应把大气干湿沉降物列为PAHs污染源。     

典型岩溶区多介质中多环芳烃的环境存在特征——以广西大石围天坑群为例

选择典型岩溶地区广西大石围天坑群为研究对象,采用2007-2008年同期采集的大气干湿沉降、空气、土壤、地下河水和沉积物样品测试数据,运用16种多环芳烃(PAHs)的成分谱、分布特征和特征比值,结合其物理化学性质进行对比分析.初步研究结果表明,全年大气干湿物/土壤/地下河沉积物均以屈(Chr)、苯并[b]荧蒽(BbF)、苯并[k]荧蒽(BkF)、苯并[a]芘(BaP)4种4～6环PAHs为主;同期天坑空气/秋冬季于湿沉降物/地下河水以萘(Nap)、芴(Flu)、菲(Phe)和蒽(Ant)4种2～3环PAHs为主;各组介质中的PAHs存在特征具有较好的一致性,但也有一定的差异.利用这种方法初步解释了岩溶地区土壤、地下河水和沉积物中PAHs污染的来源(或输入);同时证明了大气干湿沉降物是偏远岩溶地区土壤和地下河中PAHs的主要来源.因此建议在污染源调查过程中应把大气干湿沉降物列为PAHs污染源.     

广西岩溶区某地下河系统多种介质中多环芳烃的分布特征

为了研究岩溶地下河系统内多种介质中多环芳烃(PAHs)的浓度、组成和分布特征,以广西某典型岩溶地下河为例,利用2013-2014年同期的空气、地下河水、沉积物和土壤样品测试数据,对不同环境介质中16种多环芳烃(PAHs)的浓度、组成和分布特征进行对比分析。结果表明,空气和地下河水以2~3环PAHs为主,其中空气的2~3环PAHs比例为71.66%,地下河水的2~3环PAHs比例为54.84%;沉积物和土壤以4~6环PAHs为主,其中沉积物的4~6环PAHs比例为54.26%,土壤的4~6环PAHs比例为65.06%;环境介质中PAHs的浓度变化为：上游<中游<下游,这与污染源排放、吸附作用等相关;同一区域不同介质的2~3环PAHs百分比为：地下河水>沉积物>土壤,而4~6环PAHs百分比则相反。     

祁连山七一冰川流域各类环境介质中多环芳烃的分布特征与来源研究

从祁连山七一冰川流域各介质中总共检测出2～7环的多环芳烃50多种,其中16种美国EPA优控物质中,只有二氢苊和二苯并[a,h]蒽没有被检测到.雪冰和冰川融水样品中相对富集3环和4环,雪冰不溶微粒和冰尘以及七一冰川周围表层土壤样品主要以4～6环为主,这是由PAHs自身的物理化学性质决定的.荧蒽/芘,菲/蒽比值表明,研究区检测出来的多环芳烃可能主要来自于化石燃料的高温燃烧,特别是煤的燃烧和机车尾气排放产生.大气污染传输与干湿沉降是七一冰川及其周围土壤中PAHs的主要输入途径.     

祁连山七-冰川流域各类环境介质中多环芳烃的分布特征与来源研究

从祁连山七-冰川流域各介质中总共检测出2～7环的多环芳烃50多种,其中16种美国EPA优控物质中,只有二氢苊和二苯并[a,h]蒽没有被检测到．雪冰和冰川融水样品中相对富集3环和4环,雪冰不溶微粒和冰尘以及七-冰川周围表层土壤样品主要以4～6环为主,这是由PAHs自身的物理化学性质决定的．荧蒽／芘,菲／蒽比值表明,研究区检测出来的多环芳烃可能主要来自于化石燃料的高温燃烧,特别是煤的燃烧和机车尾气排放产生．大气污染传输与干湿沉降是七-冰川及其周围土壤中PAHs的主要输入途径．     

重工业区高脆弱岩溶含水层中多环芳烃污染的初步研究

以西南岩溶地区某市重工业区为研究对象,采集水文地质单元内地下水和土壤样品,利用气相色谱-质谱法（GC-MS)测试美国环保署16 种多环芳烃（PAHs）优控物。初步研究表明,研究区地下水16种PAHs均被检出,浓度为1 135.79～1 361.26 ng/L,以菲、蒽、萘、屈、芘为主;地下水处于中等污染程度,其中苯并[a]蒽、屈、苯并[b]荧蒽、苯并[k]荧蒽4种浓度超过美国EPA2009《国家推荐的优先有毒污染物水质标准》标准;PAHs特征比值显示含水层中的PAHs来源于燃煤和炼焦污染源,与钢铁厂和化肥厂排放的特征有机污染物一致。研究区污染源下游大面积区域地下水已经受到PAHs污染,且出现排泄区PAHs浓度高于径流区的现象,岩溶含水层PAHs的污染主要受两方面影响:一是洼地、裂隙发育,断层破碎带和强风化白云岩等为PAHs在含水层中的运移提供了有利条件,同时污染源区内地下水大量开采加速了污染物向地下水的入渗;二是水电站建坝蓄水发电,江水水位抬高,河岸地下水排泄速度减慢,可能致使岩溶含水层中PAHs的自净能力减弱。生态风险评价显示地下水中菲、蒽、芘、苯并[a]蒽、苯并[b]荧蒽处于重污染风险,应采取措施降低污染风险。      

若尔盖草原泥炭柱中多环芳烃的沉积记录

通过210Pb定年建立相应时间标尺,获得了若尔盖红原县泥炭柱中多环芳烃(PAHs)的含最和垂直分布特征.结果表明,泥炭中总PAH8的浓度为36.2～408ng/g dw,PAHs与泥炭TOC的含量具有较好的相关性.自20世纪初开始,PAHs浓度呈明显上升趋势,在1960年代初期达到峰值,其后开始下降.PAHs组成上主要以3～4环化合物为主,其中菲占总PAHs的45%,其次是荧蒽(16%)和芘(10%),体现出大气沉降来源的PAHs组成特征.PAHs成因判识指标表明,该地区泥炭中PAHs主要源自燃煤和汽车尾气排放;结合气流轨迹分析,我们认为四川盆地可能是其主要源区.泥炭中PAHs的浓度变化与泥炭TOC的含量、温度和降雨量有关.     

长江口启东—崇明岛航道沉积物中多环芳烃分布来源及生态风险评价

近年来我国长江河口有关沉积物中多环芳烃(PAHs)污染的研究主要集中在长江口近海及上海主城区滨岸等区域,而长江口航道则鲜有报道。本文在长江口启东—崇明岛航道区域采集表层(0~20 cm)沉积物样品,利用加速溶剂萃取技术提取,用高效液相色谱-荧光检测器对14种PAHs进行测定,研究其分布特征、环境来源和潜在的生态风险。研究结果显示,PAHs在所有沉积物样品中均有不同程度的检出,浓度范围为83.43~5206.97 ng/g,平均值736.95 ng/g。就PAHs单体而言,含量较高的是2~4环污染物,其中菲的含量最高,占各点位PAHs总量的9.04%~24.06%;其次为荧蒽和芘;具有高致癌性的苯并(a)芘在各个点位均能检出,占PAHs总量的0.94%~10.68%。与国内外类似河口和近海海域相比,本研究区PAHs处于中等污染水平。利用比值法解析PAHs的来源,菲/蒽(Phe/Ant)10且荧蒽/芘(Fla/Pyr)≥1的点位占所有采样点位的56.25%,表明区域内PAHs的主要来源是化石燃料的高温燃烧;位于航运码头附近采样点位的PAHs以石油源为主,部分点位呈化石燃料源和石油源混合污染特征。对照风险效应低值(ERL)和风险效应中值(ERM)进行初步风险评价,表明研究区域部分采样点位的PAHs具有潜在的生态风险。     

华北地区下古生界海相烃源岩芳烃生物标志物地球化学特征——兼论饱 …

本文详细总结了华北地区下古生界海相烃源岩中芳烃生物标志的特征,主要包括菲系列联苯系列、苯并芴系列、三芴系列、荧蒽系列、芘系列、苯并荧蒽和苯并芘系列、屈系列和三芳甾烷系列,而萘系列含量较低。我们发现三苯甾烷Ｃ２８（２０Ｓ）／Ｃ２８（２０Ｒ）比值似乎显示了较了的热演化特征。     

柴达木盆地北缘中侏罗统石门沟组煤中多环芳烃分布特征及其地质意义

多环芳烃(PAHs)是古环境、古野火以及古气候的重要地质记录,本文通过气相色谱质谱法(GC- MS)研究了柴达木盆地北缘中侏罗统石门沟组煤中多环芳烃分布特征,检测出一系列二环至七环芳烃化合物,包括高等植物衍生多环芳烃(卡达烯、6- 异丙基- 1- 异己基- 2- 甲基萘、惹烯、西蒙内利烯以及二氢惹烯)和燃烧衍生多环芳烃(荧蒽、芘、苯并\[a\]蒽、、苯并荧蒽、苯并\[e\]芘、苯并\[a\]芘、茚并\[cd\]芘、苯并\[ghi\]苝和晕苯)等。这些多环芳烃的检出表明石门沟组煤沉积于具有显著陆源高等植物输入的微咸水湖沼环境,成熟度较低(平均随机反射率为056%)。石门沟组煤中高等植物衍生多环芳烃以极高的惹烯含量为特征,且存在较高丰度的西蒙内利烯和二氢惹烯,卡达烯丰度极低,反映出成煤期陆地植被类型以松柏类植物的针叶林为主,气候温暖湿润。同时,煤中丰富的燃烧衍生多环芳烃证实了柴达木盆地北缘中侏罗世存在广泛的陆地古野火,较高的大气氧气浓度(256%)可能是该时期野火频发的一个重要诱因。本次研究为柴达木盆地中侏罗世古野火事件的研究提供了重要的分子化石证据,也是对中侏罗世古环境和古气候研究的有益补充。     

Sources and transports of polycyclic aromatic hydrocarbons in the Nanshan Underground River,China

Karst areas have much higher ecological vulnerability and are easy to be contaminated by polycyclic aromatic hydrocarbons (PAHs), which are introduced as health risk pollutants. PAHs ratios were used to understand the sources and transport behavior of PAHs conducted in the karst Nanshan Underground River, China. Water, sediments from the underground river and water, sediments, soil from the surface were collected monthly in 2011 and 2012. Abundant PAHs were found both in the underground river and in the surface system. The detected ΣPAHs concentrations varied from 353 to 13,203 ng L^?1 in the groundwaters and content from 169 to 12,038 ng g^?1 in the sediments of the underground river. The ratios of anthracene to anthracene, plus phenanthrene and fluoranthene to fluoranthene, plus pyrene indicated that PAHs were delivered in the groundwaters from combusted grass, wood, and coal, while in the sediments were a mixture of non-combusted petroleum, grass, wood, coal and combusted grass, wood, coal. The similarities in sources between an underground river and surface system indicated that farmlands play a major role for the transport of PAHs and contamination in the underground river. Karst features are liable for the transport behavior.     

Sources and contamination characteristics of PAHs in environmental media in a karst underground river system (southern China)

The aim of this study was to determine the sources and contamination characteristics of polycyclic aromatic hydrocarbons (PAHs) in various environmental media in a karst underground river system. For this purpose, air, underground river water, sediment, and soil samples were collected from a typical underground river in southern China in the dry and wet seasons of 2013–2014, and the compositional spectra, distribution, and ratio characteristics of 16 PAHs were determined for comparative analysis. The results show that three 2–3-ring PAHs (naphthalene, phenanthrene, and fluoranthene) mainly occur in air and underground river water. In sediments and soils, 4–6-ring PAHs are the main components. The PAH concentrations in the air in the wet season are clearly greater than those in the dry season, while it is the opposite in the underground water. Seasonal differences in the concentration of PAHs in the sediments and soils are minor. The concentrations of PAHs in the environmental media overall showed variation in the following order: upstream < midstream < downstream, and this is related to pollutant discharge, adsorption, etc. The main source of PAHs in the upstream area is the combustion of grass, wood, and coal, while it is petroleum in the midstream area, and combustion of grass, wood, coal, and petroleum near the outlet of the underground river. It is necessary to change the energy structure in the study area, improve the efficiency of environmental protection facilities, reduce the emission in vehicle exhaust, and control pollution by PAHs at their sources.     

Urban and suburban storm water runoff as a source of polycyclic aromatic hydrocarbons (PAHs) to Massachusetts estuarine and coastal environments

Urban and suburban storm water runoff from ten locations in eastern Massachusetts was analyzed for 39 polycyclic aromatic hydrocarbons (PAHs) compounds. Similar profiles in PAH composition were observed for groups of samples and appear to reflect land use. The largest group includes, urban storm water from areas with a mix of industrial, commercial, and residential use. Fluoranthene, phenanthrene, pyrene, chrysene, and benzo (b) fluoranthene were the predominant compounds in this group, but lighter molecular weight PAHs were also present. Sources of PAHs to storm water include a combination of petroleum and combustion. The profile of PAH compounds in local atmospheric deposition was similar to urban storm water, but differed in several of the predominant compounds. PAHs in storm water could increase the levels of these compounds in nearshore sediments and may be the most important source of high molecular weight PAHs to these environments.     

Polycyclic aromatic hydrocarbons in the soils of technogenic landscapes

An integrated study of qualitative and quantitative composition of polycyclic aromatic hydrocarbons (PAH) in the atmospheric precipitation-soil-lysimetric water system of aerotechnogenic polluted landscapes was conducted using high-performance liquid chromatography in a gradient mode. Only low-molecular weight polyarenes (phenanthrene, anthracene, fluoranthene, pyrene, benz(a)anthracene, and chrysene) were found in the atmospheric precipitation and lysimetric waters. The growth of PAHs in soils is provided by the input of phenanthrene, fluoranthene, and pyrene with atmospheric precipitation. The absence of heavy PAHs (benzfluoranthenes, benz(a)pyrene, dibenz(a,h)anthracene, benz(ghi) perylene, and indeno[1,2,3-cd]pyrene) in the atmospheric precipitation and their identification in soil give grounds to state that their accumulation was caused mainly by transformation of organic matter during pedogenesis. The technogenic impact was estimated and criterion of the degree of soil pollution by PAH was proposed.     

Distribution of polycyclic aromatic hydrocarbons in recent sediments of Sundarban mangrove wetland of India and Bangladesh: a comparative approach

The present work is the first attempt to compare the data of a comprehensive study of the origin and distribution of 16 priority pollutant polycyclic aromatic hydrocarbons (PAHs) in surface sediments (<63 μm) from 18 sampling stations, 9 from Sundarban of Bangladesh and 9 from Indian counterpart. Σ19PAHs concentration in sediments showed wide variations from 208.3 to 12,993.1 ng g^?1 dry weight in Indian Sundarban, whereas 208.4 to 4,687.9 ng g^?1 in the case of Bangladesh. Fluoranthene, pyrene, benzo(b)fluoranthene, benzo(a)pyrene and dibenzo(a,h)anthracene were predominant species for both the countries. The PAH diagnostic ratios indicated that the PAHs in sediments from both the countries were of mixed source of hydrocarbons of both petrogenic and pyrolytic origin. According to the numerical effect-based sediment quality guidelines, the levels of PAHs in the Sundarban wetland of Bangladesh and India should not exert adverse biological effects. The TEQ values calculated for samples from the Bangladesh and Indian Sundarban varied from 13.68 to 1,014.75 and 1.31 to 2,451 ng g^?1 d.w. with an average of 221.02 and 358.63 ng g^?1, respectively. The overall contamination status of PAH was higher in India than Bangladesh.     

Atmospheric sources and soil filtering of PAH content in karst seepage waters

The analysis of PAHs (polycyclic aromatic hydrocarbons) in karst environments has provided an assessment of the vulnerability of karst water and the study of PAH records in stalagmites. The major source of PAHs has generally been considered to be the soil. In this study, we report the quantification of PAHs in the ecosystem compartments of a mountain karst system over a snow-melting period and the spring to summer dry period. PAH profiles in karst seepage waters were consistently similar to those in wet deposits, following the change in PAH profiles between winter and summer periods. However, PAH signatures of atmospheric wet deposits were modulated by a loss of the high molecular weight PAHs, which appear to accumulate in soils. A PAH mass balance was calculated during a summer storm event. This mass balance suggests that dry deposits and canopy throughfall could account for the PAH abundance in karst seepage waters. This study demonstrates the ability of organic hydrophobic compounds to be directly transferred from the atmosphere or canopy into seepage waters, giving new emphasis to the study of PAHs recorded in stalagmites.     

Polychlorinated biphenyls in the Nanshan Underground River, China

Abstract Karst areas have much higher ecological vulnerability and are easy to be contaminated by polychlorinated biphenyls(PCBs) which are introduced as health risk pollutants.PCBs concentrations were used to understand the transport behavior of PCBs conducted in the karst Nanshan Underground River,China.Water and sediments from the underground river water,and sediments and soil from the surface of the corresponding watershed were collected monthly in 2011 and 2012 and PCBs were analyzed.Seasonal variations were found in concentrations of PCBs both in the waters and sediments.PCBs concentrations varied from 0.3 to 29.9 ng·L-1 in the groundwater,while from 0.1 to 366.1 ng·g-1 in the underground sediments.Correlations were found in concentrations of PCBs in waters and sediments between the underground river and surface systems which indicate that the surface systems play a major role for the transport of PCBs and contamination in the underground river systems.Karst features are liable for the transport behavior.The underground river waters transport PCBs at mean 3 g·day-1.     

Promoted dissipation of phenanthrene and pyrene in soils by amaranth (<Emphasis Type="Italic">Amaranthus tricolor</Emphasis> L.)

A study was conducted to investigate the performance of amaranth, a known hyperaccumulator of cesium, on the promotion of the dissipation of soil phenanthrene and pyrene, which are PAHs (polycyclic aromatic hydrocarbons). Amaranthus tricolor L. een choi was the cultivar used. The presence of Amaranthus tricolor L. evidently enhanced the dissipation of these PAHs in soils with initial phenanthrene concentrations of 7.450–456.5 mg/kg dw (dw, dry weight) and pyrene of 8.010–488.7 mg/kg dw. At the end of the experiment (45 days), the residual concentrations of phenanthrene and pyrene in spiked soils with plants were generally higher than those with no plants. The loss of phenanthrene and pyrene in vegetated soils was 87.85–94.03% and 46.89–76.57% of the soil with these chemicals, which was 2.55–13.66% and 11.12–56.55% larger than the loss in non-vegetated soils, respectively. The accumulation of phenanthrene and pyrene by the plant was evident. Root and shoot concentrations of these chemicals monotonically increased with increasing soil PAH concentrations. Bioconcentration factors (BCFs), defined as the ratio of chemical concentrations in plants and in the soils (on a dry weight basis), of phenanthrene and pyrene by roots were 0.136–0.776 and 0.603–1.425, while by shoots were 0.116–0.951 and 0.082–0.517, respectively. BCFs of phenanthrene and pyrene tended to decrease with the increasing concentrations of soil phenanthrene and pyrene. Plant accumulation only accounted for less than 0.32% (for phenanthrene) and 0.33% (for pyrene) of the total amount enhancement of the dissipated PAHs in vegetated vs. non-vegetated soils. In contrast, plant-promoted microbial biodegradation was the predominant contribution to the plant-enhanced dissipation of soil phenanthrene and pyrene. These results suggested the feasibility of the radionuclide hyperaccumulator in phytoremediating the soil PAH contaminants.     

Source identification of polycyclic aromatic hydrocarbons in sediments of a creek around a flow station

Sources of the sixteen polycyclic aromatic hydrocarbons (PAHs) in the United States Environmental Protection Agency priority pollutants list were determined in sediments of Kolo Creek using diagnostic ratios of parent PAHs[phenanthrene/phenanthrene + anthracene; fluoranthene/fluoranthene + pyrene; benz(a) anthracene/benz(a) anthracene + chrysene and indeno(1,2,3-d)pyrene/indeno(1,2,3-cd)pyrene + benzo(ghi)pyrelene]. The study was conducted over four seasons (dry, late dry, rainy and late rainy seasons). Applying cross plots of the diagnostic ratios revealed that PAHs in Kolo Creek sediment have pyrogenic origins except in the rainy season that had petrogenic origins. Comparison of diagnostic ratio values obtained from this study with literature values enabled the further classification into types of pyrogenic and/or petrogenic sources. While the pyrogenic sources of PAHs were mainly as a result of Grass/Wood combustion, the petrogenic PAHs were as result of drained diesel and lubricating oil. The predicted sources corresponded with the prevailing human activities in the vicinity, especially samples collected near a petrol station and an abattoir. This study further affirms the simplicity and accuracy of the use of diagnostic ratios for PAHs source prediction.