佳木斯市土壤中酞酸酯类污染调查及评价

对佳木斯市农业土壤中酞酸酯类污染物含量进行了调查。在佳木斯市市区及6个县市采集土壤样品184个进行分析。监测结果表明，土壤中酞酸酯浓度（∑PAEs）为未检出～10298．9μg／kg，检出率为89．1％。DEHP为主要污染物，检出率为88．0％，均值为1999．2μg／kg，最高浓度为8577．4μg／kg。DMP检出率最低，为0．5％。     

天津市空气颗粒物中酞酸酯的分布特征

采用气相色谱-质谱仪(GC-MS)对天津市空气颗粒物中15种酞酸酯(PAEs)夏季和冬季的浓度进行了分析测定,研究了酞酸酯污染水平的季节变化,不同季节酞酸酯的功能区差异,15种酞酸酯在颗粒物中的分布特征,以及DBP和DEHP在夏冬两季中的污染特点,分析了产生上述结果的原因,基本说明了天津市空气颗粒物中酞酸酯的污染状况和特点。     

鞍山市空气颗粒物中酞酸酯的季节变化与功能区差异

采用气相色谱-质谱仪(GC-MS)对辽宁省鞍山市空气颗粒物中15种酞酸酯夏季和冬季的浓度进行了分析测定,研究了酞酸酯污染水平的季节变化,不同功能区酞酸酯浓度的差异,以及DBP和DEHP在夏冬两季中的污染特点,将鞍山市夏冬两季酞酸酯的浓度与国内外部分城市进行了比较,分析了产生上述结果的原因,基本说明了鞍山市空气颗粒物中酞酸酯的污染状况。     

水中酞酸酯类化合物的测定

通过筛选水中酞酸酯类化合物的萃取条件，优选出方法简单、回收率高的萃取方法，利用GC—FID和GC—MS—SIM检测，证明筛选的方法稳定可靠，平均回收率在98．1％～105％，在能力验证中获得了满意的结果。     

花垣河锰污染及其成因分析

对花垣河河水中8个监测断面（S1-S8）水样和堆积在河岸附近MnSO4废渣及其浸出液中Mn、Cd、Pb、Cu和Zn等5种重金属元素的总量进行了分析。结果表明，花垣河河水中Mn和Cd质量浓度超过《地表水环境质量标准》（GB3838—2002）V类水体标准；MnSO4废渣浸出液中Cd超过《危险废物鉴别标准》（GB5058．3—1996）规定值。将花垣河河水中Mn、Cd、Pb、Cu和Zn的含量与MnSO4废渣浸出液中相应的元素含量进行相关性分析，r=0．957（P〈0．01），表明堆积在花垣河河岸附近MnSO4废渣是可能造成花垣河污染的主要来源。     

某钢丝绳典型产业区土壤重金属含量现状调查

以钢丝绳产业集聚区内的土壤为研究对象，采集和分析产业区中心河两边淹水环境下的水稻田、少用受污染河水灌溉的棉花田及不用受污染河水灌溉的蔬菜地样本，结果表明，产业区内土壤中铅和锌的含量明显高于产业区外。产业区内除水稻田土壤中铅的质量比超过评价参比值外，其他灌溉方式下土壤中铅和锌的质量比均未超过《土壤环境质量标准》（GB 15618-1995）中的二级标准（pH值＞7）。统计分析表明，土壤中的重金属含量与废水灌溉方式有关，该产业区内土壤外源重金属来自钢丝绳产业的可能性很大。在不同的灌溉方式下，土壤剖面样品中的重金属含量随着土壤深度增加呈现降低的趋势，2010年和2011年的测定结果无显著差异。     

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。     

ASE-GC-MS法测定土壤中酞酸酯类有机物质量控制指标探索

用ASE(加速溶剂萃取)-GC-MS法测定土壤中酞酸酯类有机物,得到平行样品157组数据、重复性实验12组数据、全程序空白55组数据、空白加标122组数据、基体加标80组数据的质量控制指标的范围值,酞酸酯类有机物的检出限为8~26μg/kg。     

九龙江龙岩段地表水中多环芳烃分布与污染源解析

用竹炭固相萃取恒波长同步荧光法测定了九龙江龙岩段水体中16种优控多环芳烃(PAHs)的含量。结果表明:龙岩市省控断面河水中2010年11月(冬季)多环芳烃的质量浓度为58.3×10-9~1 328.5×10-9g/L,平均为387.72×10-9g/L;2011年9月(秋季)水中总多环芳烃质量浓度为5.9×10-9~188.4×10-9g/L,平均为77.46×10-9g/L;7月(夏季)多环芳烃的质量浓度为16.7×10-9~1 203.3×10-9g/L,平均为475.05×10-9g/L,同国内外河流相比,九龙江龙岩段水体中PAHs污染较严重,且具有明显的季节分布特征。夏、秋、冬季九龙江龙岩段水体水中均以3~4环PAHs为主。污染来源分析表明,河水中PAHs主要来源于燃烧源。     

重庆典型岩溶区地下河水体PAEs分布特征研究

分别采集了重庆典型岩溶区5条地下河水体10个样品,用气相色谱法对样品中的邻苯二甲酸酯类(PAEs)含量进行测定,分析其在重庆典型岩溶区地下河水体中的分布特征。结果表明,常见的19种邻苯二甲酸酯类(PAEs)在重庆典型岩溶区地下河水体中均有检出,其浓度范围为103.29~2268.78μg/L;5种被美国环保局列为优先控制的PAEs类污染物中,邻苯二甲酸二丁酯(DBP)和邻苯二甲酸双(2-乙基己基)酯是主要的污染物;与国内外其他地区水体进行比较,重庆典型岩溶区地下河水体PAEs含量处于较高污染水平。     

Flame ionization gas chromatographic determination of phthalate esters in water, surface sediments and fish species in the Ogun river catchments, Ketu, Lagos, Nigeria

The detection and quantification of four phthalate esters??dimethyl phthalate (DMP), diethyl phthalate (DEP), dibutyl phthalate (DBP), and diethylhexyl phthalate (DEHP)??in water, sediment, and some fish species were carried out using flame ionization gas chromatography. The samples were collected from the Ogun river catchments, Ketu, Lagos. The DMP was not detected in the water and fish samples but was detected in sediments collected from four of the six sampling sites. The concentration of DEP, DBP, and DEHP in the fish species ranged from 320.0?C810.0, 380.0?C1,080.0, and 40.0?C150.0 ??g/kg in Tilapia sp.; 310.0?C860.0, 400.0?C1,170.0, and 40.0?C110.0 ??g/kg in Chrysichthys sp.; and 320.0?C810.0, 400.0?C3,970.0, and 30.0?C300.0 ??g/kg (DEHP) in Synodontis sp., respectively. The differences in fish phthalate levels are not statistically significant at p?<?0.05, an indication that phthalate esters accumulation is not fish species dependent. The DEP, DBP, and DEHP values recorded are considerably higher than the maximum allowed concentrations for drinking water prescribed by the US Environmental Protection Agency. The phthalate pollution index and biosediment accumulation factor values were also calculated.     

Survey of Levels of Phthalate Ester Plasticizers in a Sewage Lagoon Effluent and a Receiving Stream

In this study, samples from a sewage treatment lagoon and those from a receiving stream were analyzed for their phthalate esters content. Knowledge of the distribution of ubiquitous phthalate esters in the sewage lagoon and the receiving stream was necessary because of the reports of their subtle toxicity to aquatic biota and humans. Liquid–liquid extraction, Clean-up experiment and High Performance Liquid Chromatography (HPLC) were the methods employed for the quantitative determination of the Phthalates. A study of uncontaminated water was done to establish blank levels. The sewage lagoon and the receiving stream were grossly polluted as several phthalate ester plasticizers: DMP, DEP, DPhP, DBP, DEHP, DOP and DINP were found present at monthly mean levels of between 24.02 mg/L and 139.25 mg/L in the sewage treatment lagoon and 10.41 mg/L and 80.53 mg/L in the receiving stream. The results showed higher levels of phthalate esters in the sewage lagoon compared to the receiving stream. The sewage lagoon was identified as a pollution point source into the receiving stream. Levels of phthalates obtained from the receiving stream are much higher than the water criteria of 3 μg/L phthalates recommended by the United States Environmental Protection Agency (USEPA) for the protection of fish and other aquatic life in water and the Suggested No-Adverse Effect Levels (SNAEL) of 7.5–38.5 μg/L for drinking water. This should give cause for great environmental concern. Peoples’ health downstream is at stake and so is the ‘health’ of the ecosystem.     

液液萃取/气相色谱法测定环境水样中邻苯二甲酸酯类化合物

建立了液液萃取-气相色谱法测定环境水样中邻苯二甲酸酯类化合物的方法。该方法能有效分离8种邻苯二甲酸酯类化合物。标准曲线线性回归相关系数均大于0．9999，最小检测量可达10^-11g，相对标准偏差为0．47％～1．83％。加标回收率为73．5％～114．6％。     

化工废水中邻苯二甲酸酯的研究

对北京市五个化工厂的废水中8种邻苯二甲酸酯类环境激素进行分析和调查研究.在化工废水中普遍检出的邻苯二甲酸酯有邻苯二甲酸二丁酯(DBP)、邻苯二甲酸二(2-乙基己基)酯(DEHP)、邻苯二甲酸丁基苄基酯(BBP)、邻苯二甲酸二环己酯(DCHP),其中邻苯二甲酸二乙酯(DEP)、邻苯二甲酸二正丙酯(DPrP)、邻苯二甲酸二戊酯(DAP)和邻苯二甲酸二正己酯(DHP)4种物质未检出.废水中DEHP和DBP的浓度均低于排放标准.     

固相萃取-气相色谱法测定水环境中邻苯二甲酸酯

采用固相萃取法对水样进行提取富集,气相色谱法测定水中6种邻苯二甲酸酯类有机污染物,并对方法进行了探索、优化和验证。对水体pH在固相萃取过程中对邻苯二甲酸酯萃取回收率的影响进行了研究,解决了邻苯二甲酸2-乙基己基酯和邻苯二甲酸二正辛酯回收率不高的问题。在空白水加标实验中,邻苯二甲酸酯的回收率能达到93.2%~116.3%。除此之外,还对工业废水和地表水进行了加标回收实验,获得了较高的回收率及测定精度。     

气溶胶PM2.5中内分泌干扰物酞酸酯类的研究

通过选择17种酞酸脂的目标化合物的特征离子对PM2.5样品进行特征离子的扫描,有效建立了高灵敏度的PM2.5酞酸脂类(PAE)的GC-MS-SIM的测定方法;检出限均达到了ng级的水平。气溶胶PM2.5中酞酸脂类(PAE)的污染特征:清洁对照点以邻苯二甲酸二丁酯(DBP)为主;二类区以邻苯二甲酸二(2-乙基己基)酯(DEHP)和邻苯二甲酸二丁酯(DBP)占主导成分。     

集中式饮用水源地邻苯二甲酸酯类物质分布特征与健康风险评估

以某地区7个集中式饮用水源地为研究对象,采用固相萃取气相色谱-质谱法(SPE-GC-MS)对水体中16种邻苯二甲酸酯的分布特征和溯源进行了研究,并利用健康风险评估模型对水体PAEs进行了健康风险评价。结果表明:邻苯二甲酸二正丁酯、邻苯二甲酸二(2-乙基己基)酯、邻苯二甲酸二异丁酯和邻苯二甲酸二正辛酯在所有PAEs同系物中含量丰富,而所有样品均无邻苯二甲酸二(2-甲氧基)乙酯和邻苯二甲酸二戊酯的检出;二水厂和亨达水务断面Σ_(16)PAEs浓度最高,四水厂和五水厂断面Σ_(16)PAEs浓度最低;水体12种PAEs共提出3个主成分,揭示了91%的影响因子;层次聚类分析表明:7个采样断面聚为2类,分别代表了内河和长江水体。水体中PAEs的致癌风险值和非致癌风险值均远低于参考值,说明研究水体PAEs不会对居民构成致癌风险或其他明显的健康风险,但需加强该地区PAEs使用的规范与监管,强化末端处理,以规避风险。     

Behavior of di(2-ethylhexyl) phthalate discharged from domestic waste water into aquatic environment

The behavior of di(2-ethylhexyl) phthalate (DEHP) discharged from domestic waste water into river water, sediment and submerged aquatic vegetation was investigated. The concentrations of DEHP were found to be between 8-25 microg L(-1) in river water, 1,000-2,000 microg kg(-1) in sediment and less than 20-2,000 microg kg(-1) in submerged aquatic vegetation. The experiments performed in laboratory were on the biodegradation of DEHP in water and sediment, and also adsorption equilibrium of DEHP between water and sediment. The results obtained from the investigations made it clear that the high enrichment of DEHP from water to sediment was caused from not only its high adsorptive potential but also slow degradation in sediment.     

Distribution of PAEs in the middle and lower reaches of the Yellow River, China

Samples of water, sediment and suspended particulates were collected from 13 sites in the middle and lower reaches of the Yellow River in China. Phthalic acid esters (PAEs) concentrations in different phases of each sample were determined by Gas Chromatogram GC-FID. The results are shown as follows: (1) In the Xiao Langdi–Dongming Bridge section, PAEs concentrations in water phase from the main river ranged from 3.99 × 10⁻³ to 45.45 × 10⁻³ mg/L, which were similar to those from other rivers in the world. The PAEs levels in the tributaries of the Yellow River were much higher than those of the main river. (2) In the studied branches, the concentration of PAEs in sediment for Luoyang Petrochemical Channel (331.70 mg/Kg) was the highest. The concentrations of PAEs in sediment phase of the main river were 30.52 to 85.16 mg/Kg, which were much higher than those from other rivers in the world. In the main river, the concentration level of PAEs on suspended solid phases reached 94.22 mg/Kg, and it reached 691.23 mg/Kg in the Yiluo River – one tributary of the Yellow River. (3) Whether in the sediment or on the suspended solid phases, there was no significant correlation between the contents of PAEs and TOC or particle size of the solid phase; and the calculated Koc of Di (2-Ethylhexyl) Phthalate (DEHP) in the river were much less than the theoretical value, which inferred that PAEs were not on the equilibrium between water and suspended solid phases/sediment. (4) Among the measured PAEs compounds, the proportions of DEHP and di-n-butyl phthalate (DBP) were much higher than the others. The concentrations of DEHP exceeded the Quality Standard in all the main river and tributary stations except those in the Mengjin and Jiaogong Bridge of the main river. This indicates that more attention should be paid to pollution control and further assessment in understanding risks associated with human health.