中国表层水体沉积物中多环芳烃源解析及评价

采用索氏提取气相色谱-质谱法测定中国6个重点水体表层沉积物中16种多环芳烃的含量。各化合物含量范围分别为长江6.20~163 ng/g、淮河7.90~249 ng/g、海河12.1~401 ng/g、松花江5.75~152 ng/g、太湖29.1~2 810 ng/g和滇池19.1~795ng/g；16种多环芳烃的总量分别为：长江1 147 ng/g、淮河1 723 ng/g、海河2 595 ng/g、松花江793 ng/g、太湖12472 ng/g、滇池3 714 ng/g，属中等污染水平。利用特征分子比值法分析结果表明6条水体表层沉积物中PAHs均可能以燃料（包括柴油、汽油、煤、木材）燃烧以及焦化污染为主。淮河和滇池还可能存在轻微石油泄漏污染。利用沉积物质量基准法（SQGs）和沉积物质量标准法分别对6条水体表层沉积物中多环芳烃的风险评估表明严重的多环芳烃生态风险在这些水体表层沉积物中不存在，但长江、淮河、松花江、海河均可能存在一定的潜在风险，负面生物毒性效应会偶尔发生，风险主要来源于荧蒽和菲。太湖和滇池水体中存在的潜在多环芳烃风险种类较多，风险主要来源于菲、荧蒽、芘、苯并（a）蒽、苊和蒽，对水生生物毒性效应较高，有必要进行更深入细致的调查研究高风险区域底栖生物的受损状况、污染来源和途径，以制定合理的污染控制对策。     

天津滨海新区黑潴河下游沉积物多环芳烃风险评价及环境基准值的比较

对黑潴河下游表层沉积物中16种多环芳烃(PAHs)的污染现状进行了调查研究。结果表明,表层沉积物中PAHs总量变化范围为41.2～129.3ng/g(平均值为83.7ng/g),PAHs的组成以5～6环PAHs组分为主。黑潴河下游沉积物中PAHs主要来源于周边地区化石燃料的高温燃烧。比较了基于不同方法建立的沉积物中PAHs环境基准值的差异,分析产生差异的原因,选择生态效应区间法对黑潴河沉积物中的PAHs进行了生态风险评价。黑潴河下游PAHs生态风险较小,属PAHs低生态风险河道。     

商丘市包河表层沉积物中多环芳烃污染初步研究

对包河表层沉积物6个位点的样品中多环芳烃进行了研究,分析其含量、分布特征及其生态风险评价,并结合采样点的情况对其进行源解析,共检测出6种多环芳烃,含量范围为0~9. 50 ng/g。按城市分布情况来看,工业厂附近多环芳烃的含量相对较高。比值法和因子分析法结果显示,多环芳烃污染主要来源于煤炭的燃烧,目前包河表层沉积物中多环芳烃含量处于低风险水平,尚未对生物造成显著的负面影响.     

南四湖上级湖表层沉积物中多环芳烃的含量及分布特征

对南四湖上级湖表层沉积物中的15种美国环保暑(US EPA)优控多环芳烃(PAHB)进行了定量分析.测定结果表明,沉积物中15种PAHs总合量范围为163.0～2983.8ng/g dry wt..相关分析表明,南四湖上级湖表层沉积物中PAHs浓度的空间分布受入湖河流影响较大,与入湖河流两岸的工农业布局和城市分布存在一定的相关性;南四湖上级湖表层沉积物中的多环芳烃主要来源于煤炭、木材及石油的不完全燃烧;目前南四湖上级湖表层沉积物样品中的PAHs含量处于低风险水平,尚未对生物造成显著的负面影响.     

广州大学城珠江水域多环芳烃的污染特征

利用GC-MS对广州大学城珠江水域的地表水及表层沉积物中多环芳烃(PAHs)的含量进行了分析。结果表明,广州大学城珠江水域及表层沉积物中均可检出PAHs,水体优控PAHs总量在1061.7~6577.8ng/L之间,沉积物中优控PAHs总量分布在896.1~7248ng/g之间。广州大学城珠江水域的PAHs属混合来源,主要有石油类产品的输入(漏油泄油)和化石燃料的燃烧(大气沉降)。     

黄河兰州段水环境中多环芳烃污染初步研究

2004年11月对黄河兰州段11个采样点的水样、悬浮颗粒物和表层沉积物中的多环芳烃(PAHs)污染作了初步研究。调查结果显示,在此河段中,16种优先控制的PAHs均有检出,总PAHs浓度范围分别为水中,2920~6680ng/L;表层沉积物中,960~2940ng/g(干重);悬浮物中,4145~29090ng/g(干重);其中含量较高的是和芘,且分子量较小的PAHs所占的比例较大。来源分析结果显示,黄河兰州段水环境中PAHs的来源是燃烧源和石油源混合的结果,为混合输入型。用生物学阈值对表层沉积物质量进行评价,黄河兰州段表层沉积物的PAHs污染不算严重,偶尔会产生负面生态效应。     

重点流域水系沉积物中多环芳烃标准样品制备

环境标准样品是监测过程中重要的质量控制手段,中国受天然基体标准样品制备技术的制约,尚未拥有自己的沉积物中多环芳烃标准样品。为制备符合中国重点流域沉积物类型及多环芳烃浓度水平的沉积物标准样品,对中国6个重点流域的沉积物进行了采样,获得了制备多环芳烃标准样品的原料。分析常温及冷冻2种干燥方式对多环芳烃的影响,为制备大批量多环芳烃标准样品提供数据支持。对11个点位样品采用气相色谱质谱法测定16种优控多环芳烃化合物浓度,结果表明,样品均匀性良好,样品中多环芳烃检出率在99%以上,江河沉积物样品中多环芳烃浓度区间为664~2.91×103μg/kg,湖泊样品最高值达到1.25×105μg/kg,其主要污染源是化学燃料的燃烧。为中国制备水系沉积物中多环芳烃标准样品积累了技术基础。     

九洲江沉积物多环芳烃和抗生素的分布特征与风险评价

利用液相色谱-三重四级杆质谱法(HPLC-MS/MS)以及超高压液相色谱法(HPLC),于2018年1月对九洲江沉积物样品中31种抗生素和16种多环芳烃(PAHs)的分布特征进行研究并评价其生态风险。结果表明,九洲江沉积物检出20种抗生素,其中四环素类(TCs)抗生素质量分数最高,或因其在养殖业用量最大且易被沉积物吸附;滩面镇（S3点位）抗生素的总质量分数（52 ng/g）最高,与附近的滩面镇生猪养殖业发达,也与S3点位正好位于污水处理厂排口下游不远处有关;沉积物中共检出15种PAHs,温泉镇（S1点位）沉积物中PAHs的质量分数最高。沉积物中,4环PAHs占比最高,说明九洲江流域PAHs主要来源于煤和木柴的燃烧。生态风险评价结果表明,TCs抗生素处于高风险水平,且高风险点集中出现在滩面镇河段（S3点位）,需要采取措施减少TCs抗生素的使用;所有点位的PAHs的生态风险均为低风险,但有部分无安全剂量的PAHs组分被检出,对九洲江生态环境存在潜在威胁。     

官厅水库沉积物表层中的有机氯农药分布特征及风险评价

采用气相色谱法对北京市官厅水库沉积物表层中持久性有机氯农药(OCPs)的残留状况进行了调查,并对有机氯农药污染水平和生态风险作出评价。结果表明:沉积物中有机氯农药总含量为8.48 ng/g～24.40 ng/g,其中HCHs和DDTs的含量较高,分别为1.11 ng/g～7.73 ng/g和2.97 ng/g～10.52 ng/g,其组分特征为来自环境的残留。与沉积物风险评估低值(ERL)和风险评估中值(ERM)对比评价沉积物中有机污染物的风险程度,官厅水库沉积物表层中的有机氯农药存在一定的生态风险。     

山美水库流域表层沉积物中DDTs农药的残留特征及风险评估

利用GC-ECD检测了山美水库流域表层沉积物中DDTs农药含量,分析了其残留与组成特征及生态风险.结果表明,表层沉积物中DDTs平均含量为4.07 ng/g,其含量范围为0.96～8.20 ng/g;DDTs含量大小顺序为桃溪与湖洋溪汇流(8.20 ng/g)>湖洋溪(4.67 ng/g)>桃溪(4.59 ng/g)>山美水库(1.96 ng/g).表层沉积物中新的DDTs输入量比较少;沉积物中DDTs主要来自于早期残留或是施用农药长期风化后的土壤;大多数采样点DDTs发生好氧生物降解,降解产物以DDE为主.对照Ingersoll风险评估标准,表层沉积物中DDTs农药残留具有较高的生态风险.     

京杭大运河王江泾断面水质达标综合治理对策

简述了京杭大运河王江泾断面水质及区域水污染现状,指出工业污染、农业面源污染、污水集中处理设施滞后、内源污染是区域水污染的主要因素。提出,对区域水环境综合整治,实现京杭大运河王江泾断面水质稳定达标,必须推进产业结构调整与空间布局优化,推进点源污染整治,推进农业面源污染治理,推进生活污染源整治,推进河道整治,提高环境监管及应急水平。     

Partitioning and sources of PAHs in wastewater receiving streams of Tianjin,China

Polycyclic aromatic hydrocarbons (PAHs) partitioning among dissolved phase, suspended particulate matter, pore water, and sediment was studied in one moderately contaminated river (Yongding New River) and two highly contaminated drainage canals (South Drainage Canal and North Drainage Canal) of Tianjin, China. PAHs concentrations in sediment (ranged from 0.2 to 195 μg/g) showed positive relations with both total organic carbon contents (ranged from 0.7% to 31.1%, dw) and black carbon contents (ranged from 0.1% to 2.1%, dw) in the sediments. Moreover, most of the measured organic carbon normalized partition coefficients of PAHs in the three streams were 0.76 to 1.54 log units higher than the predicted values. These indicated that strong and nonlinear sorption of PAHs by carbonaceous geosorbents such as black carbon (BC) existed in the streams, and BC was an important part of the carbonaceous particles controlling the partitioning of PAHs in the sediments of this study. PAH component ratio analyses suggested that PAHs in the three streams, effluent samples from wastewater treatment plants, and soil samples by the riverbank had similar main sources, which is coal/petroleum combustion. We suggested the transportation and transformation of both carbonaceous particles and PAHs during wastewater treatment process, surface runoff, etc, should be studied further in order to make decisions on PAHs controlling measures.     

Distribution and sources of polycyclic aromatic hydrocarbons in Wuhan section of the Yangtze River, China

Polycyclic aromatic hydrocarbons (PAHs) are important organic contaminants with great significance for China, where coal burning is the main source of energy. In this study, concentrations, distribution between different phases, possible sources and eco-toxicological effect of PAHs of the Yangtze River were assessed. PAHs in water, suspended particulate matters (SPM) and sediment samples at seven main river sites, 23 tributary and lake sites of the Yangtze River at the Wuhan section were analyzed. The total concentrations of PAHs in the studied area ranged from 0.242 to 6.235 μg/l in waters and from 31 to 4,812 μg/kg in sediment. The average concentration of PAHs in SPM was 4,677 μg/kg, higher than that in sediment. Benzo(a)pyrene was detected only at two stations, but the concentrations were above drinking water standard. The PAHs level of the Yangtze River was similar to that of some other rivers in China but higher than some rivers in foreign countries. There existed a positive relationship between PAHs concentrations and the TOC contents in sediment. The ratio of specific PAHs indicated that PAHs mainly came from combustion process, such as coal and wood burning. PAHs may cause potential toxic effect but will not cause acute biological effects in sedimentary environment of the Wuhan section of the Yangtze River.     

Concentrations of polycyclic aromatic hydrocarbon in the surface sediments from inter-tidal areas of Kenting coast,Taiwan

The main objective of this study was to investigate the concentrations of polycyclic aromatic hydrocarbons (PAHs) in inter-tidal sediments of the Kenting coast, Taiwan, to assess the levels and origin of PAHs, and to provide useful information on the potential ecological risk of PAHs to benthic organisms. The total concentrations of 38 PAHs ranged from 0.2 to 493 ng/g dry weight. The high variation in total PAH concentrations was caused by the sand content of the sediment in the area. Compared with other coasts and bays in the world, the concentrations of PAHs in the inter-tidal surface sediment of the Kenting coast is low to moderate. Based on the sediment quality guidelines, the total PAH concentrations were below the effects range low value, indicating that the PAH levels in the Kenting area were within minimal effects ranges for benthic organisms. Principal component analysis and isomer ratios were analyzed to identify the contamination source in the inter-tidal surface sediment of the Kenting coast. The results of compounds’ pattern and origin analysis suggest that the source of PAHs in the inter-tidal surface sediment of the Kenting coast is the combustion of petroleum and biomass.     

Polycyclic aromatic hydrocarbons in surface water and bed sediments of the Hungarian upper section of the Danube River

This study was performed to elucidate the distribution, concentration trend and possible source of polycyclic aromatic hydrocarbons (PAHs) in surface water and bed sediments of the Hungarian upper section of the Danube River and the Moson Danube branch. A total of 217 samples (water and sediments) were collected from four different sampling sites in the period of 2001–2010 and analysed for the 16 priority US Environmental Protection Agency PAHs. Concentrations of total 16 PAHs (∑PAHs) in water samples ranged from 25 to 1,208 ng/L, which were predominated by two- and three-ring PAHs. The ∑PAH concentrations in sediments ranged from 8.3 to 1,202.5 ng/g dry weight. Four-ring PAHs including fluoranthene and pyrene were the dominant species in sediment samples. A selected number of concentration ratios of specific PAH compounds were calculated to evaluate the possible sources of PAH contamination. The ratios reflected a pattern of pyrogenic input as a major source of PAHs. The levels of PAHs determined were compared with other sections of the Danube and other regions of the world.     

Spatial and temporal distribution of polycyclic aromatic hydrocarbons (PAHs) in sediments of the Nansi Lake, China

Polycyclic aromatic hydrocarbons (PAHs) were measured in surface sediments and dated core sediments from the Nansi Lake of China to investigate the spatial and temporal distribution characteristics. The concentrations of 16 kinds priority PAH compounds were determined by GC-MS method. And ²¹⁰Pb isotope dating method was used to determine the chronological age of the sediment as well as the deposition rate. The results indicated that the total PAHs concentration ranges in surface and core sediment samples were 160 ~32,600 and 137 ~ 693 ng/g (dry wt.), respectively. The sediment rate and the average mass sedimentation were calculated to be 0.330 cm·year^???1 and 0.237 g·cm^???2·yr^???1 and the sediment time of the collected core sample ranged from 1899 to 2000. The peak of PAH concentrations came at recent years. The source analysis showed PAHs mainly came from the contamination of low temperature pyrogenic processes, such as coal combustion. The PAHs concentrations were lower than ERL and LEL values for most collected samples. However, in several surface sediment samples especially in estuary sites, the PAHs concentrations were not only higher than ERL and LEL values, but also higher than ERM values.