多环芳烃在珠江口表层水体中的分布与分配

为了解河口海岸带水体中多环芳烃(PAHs)的时空分布及其在水体及颗粒相中的分配及其控制因素,于2003年4月(春季)和2002年7月(夏季)采集了珠江河口及近海表层水体,采用GC-MS分析了水体中PAHs.结果表明,珠江河口及近海表层水体中多环芳烃浓度春季(颗粒相:4.0～39.1 ng/L;溶解相:15.9～182.4 ng/L)高于夏季(颗粒相:2.6～26.6 ng/L,溶解相:13.0～28.3 ng/L).河流径流、悬浮颗粒物含量及光降解程度是控制水体PAHs浓度的主要因素.水体中以3环PAHs为主,伶仃洋内样品比珠江口外样品相对富集5,6环PAHs,夏季样品较春季样品相对富集3环PAHs.颗粒物的来源和组成是造成这种差别的主要原因.PAHs在颗粒相及水相中的分配系数(Kp)随颗粒有机碳含量、水体盐度增加而增加,随悬浮颗粒物含量增加而减少.有机碳归一化分配系数(1gKdc)与辛醇/水分配系数(1gKow)间存在明显的线性关系,但高于线性自由能关系模拟值.     

Phytoremediation for phenanthrene and pyrene contaminated soils

Phytoremediation of soil contaminated with phenanthrene and pyrene was investigated using twelve plant species. Plant uptake nd accumulation of these chemicals were evaluated. At the end of the experiment(45 d), the remaining respective concentrations of soil henanthrene and pyrene in spiked vegetated soils, with initial phenanthrene of 133.3 mg/kg and pyrene of 171.5 mg/kg, were 8.71-16.4 nd 44.9-65.0 mg/kg, generally 4.7%-49.4% and 7.1%-35.9% lower than their concentrations in the non-vegetated soils. The loss f phenanthrene and pyrene in vegetated spiked soils were 88.2%-93.0% and 62.3%-73.8% of the added amounts of these ontaminants, respectively. Although plant uptake and accumulation of these compounds were evident, and root concentrations and RCFs(root concentration factors; defined as the ratio of PAH concentrations in roots and in the soils on a dry weight basis) of these compounds ignificantly positively correlated to root lipid contents, plant uptake and accumulation only accounted for less than 0.01% and 0.23% of the nhanced loss of these chemicals in vegetated versus non-vegetated soils. In contrast, plant-promoted microbial biodegradation was the ominant mechanism of the phytoremediation for soil phenanthrene and pyrene contamination. Results from this study suggested a easibility of the establishment of phytoremediation for soil PAH contamination.     

渤海湾潮滩不同粒径沉积物中多环芳烃的分布

利用湿筛分离的方法,将采自渤海湾潮间带的沉积物分成0.063mm 3个不同的粒径组分,测定其16种EPA规定的多环芳烃(PAHs)含量、总有机碳(TOC)和碳黑(BC)含量.结果表明,不同粒径沉积物中∑PAHs含量范围在714~4870ng/g之间.在岐口(TS3)沉积物中,∑PAHs含量最高值出现在0.063mm粒径组分中.所有站点沉积物的0.031~0.063mm粒径组分中∑PAHs含量均为最低.尽管如此,有机碳标准化∑PAHs含量则随着沉积物粒径的增大呈现增加趋势.不同粒径沉积物中∑PAHs含量与BC含量之间呈现显著正相关关系,而与有机碳(OC=TOC-BC)含量之间的相关性较差.因此,不同粒径沉积物中BC的分布很可能在其中扮演着更重要的作用.     

厦门西港表层海水中多环芳烃(PAHs)的含量、组成及来源

通过 3个航次对厦门西港表层海水中 16种优先监控的PAHs的污染状况进行不同季节的连续调查 .结果表明 :表层海水中PAHs的含量与组成具有明显的时间差异 .在 4月和 10月的PAHs含量较 7月高 ;PAHs的组成在 4月以 2环的萘为优势组分 ,在 7月以 3环的苊烯为优势组分 ,10月以 4环的为优势组分 .分析 3个航次的调查结果发现 :厦门西港表层海水中的PAHs主要来源于石油类物质的输入 .厦门西港表层海水中各种PAHs的含量与国际生物学组织或国家制定的评价水生生物暴露于水体的安全食用标准相比虽未超标 ,但个别组分如蒽、苯并 [a]芘的含量已达到生态毒理评价标准 .     

珠江三角洲表层水中多环芳烃的季节分布、来源和原位分配

分别于2011年4月(春季)和2011年9月(夏季)采集珠江广州河段及东江东莞河段表层水体样品,对该区域表层水体中优控多环芳烃(PAHs)的时空分布、固液分配及其来源进行了分析和讨论.结果表明,珠江广州河段及东江东莞河段表层水体中多环芳烃浓度春季高于夏季.藻类有机碳是该水环境有机碳的主要成分.溶解有机碳(DOC)、颗粒态有机碳(POC)以及叶绿素a(Chl a)含量是控制水体PAHs浓度的主要因素,说明水环境的富营养化程度可以通过增长的浮游生物量来影响多环芳烃的生物地球化学过程,继而影响其环境行为和归宿.多环芳烃在水/颗粒物间的有机碳归一化分配系数(log Koc)与辛醇/水分配系数(log Kow)间存在明显的线性关系,其斜率是夏季大于春季,可能与多环芳烃的非平衡吸附有关.多环芳烃同系物比值法和主成分分析(PCA)的结果表明,研究区域水体中PAHs主要来源于石化燃料、煤和生物质的混合燃烧,并且PAHs的来源未体现出明显的季节变化.通过本研究我们能够比较全面的了解该流域多环芳烃的时空分布状况,固液分配及其可能的来源,并且为珠江广州河段及东江东莞河段多环芳烃污染的控制和生态风险评价提供科学依据.     

深圳湾生态系统多环芳烃(PAHs)特征及其生态危害

2004年在深圳湾海域采集海水、悬浮物、表层沉积物和柱状沉积物样品,并分析其中15种多环芳烃的含量及其相关参数,同时采用210Pb法测定柱状沉积物的年龄.结果表明,海水、悬浮物、表层沉积物和柱状沉积物中总的PAHs含量分别为(69.4±24.7)ng·L-1、(429.1±231.8)ng·g-1、(353.8±128.1)ng·g-1和(321.1±134.6)ng·g-1,各介质优势组分均为菲、荧蒽和芘;1948～2004年期间,深圳湾柱状沉积物中PAH各单体的浓度总体上一直在增加,PAHs的平均沉积通量为89.9ng/(cm2·a);PAH各单体在沉积物/海水中的分配系数(Koc)与其相应的辛醇/水比(Kow)存在明显的正相关性,即可用PAH的Kow值来预测深圳湾海域PAH的Koc.目前,水体与沉积物中PAH含量对该海域的水生生物尚未构成威胁.     

多环芳烃在西江高要段水体中的分布与分配

为了解西江流域水体中多环芳烃(PAHs)的深度和季节分布及其在溶解相和颗粒相的分配以及控制因素,分别在洪水期(2003年8月和2004年7月)和枯水期(2003年11月和2004年3月)采集了西江高要段水柱.结果表明,溶解相和颗粒相中PAHs的浓度分别为21.7~138 ng/L和40.9~664.8μg/kg;水体中PAHs的总含量(颗粒相及溶解相),洪水期大于枯水期.在溶解相中,PAHs的浓度随深度无明显规律;而在颗粒物中,PAHs的浓度都表现出相同的变化趋势,即中层水PAHs含量最高,表层水PAHs含量最低.溶解相和颗粒相中PAHs的浓度都随悬浮颗粒物的含量增加而增加.从PAHs组成特点来看,溶解相以3环的PAHs为主,而颗粒相以3~4环的PAHs为主.PAHs在颗粒相及溶解相中的分配系数(KP)不受颗粒有机碳浓度控制(R2为0.000 1~0.2),而受颗粒物浓度、及溶解有机碳浓度的共同影响(R2为0.15~0.36),尤其是溶解态的细小碳黑有机质的影响.西江高要段水体PAHs在不同季节的lgKOC值大部分超过经典平衡分配模型的上限.除了2003年11月(R2为0.000 4~0.12,p0.001)之外,其它3个季节PAHs的lgKOC与lgKOW均有较强的相关性(R2为0.29~0.91,p0.05).洪水期颗粒物的亲脂性强于枯水期.     

多环芳烃在长江口滨岸颗粒物-水相间的分配

利用长江口滨岸水环境中颗粒相与溶解相多环芳烃的实测浓度,获取了多环芳烃化合物在颗粒物-水相间的分配系数K_p.结果表明,分配系数K_p值在507～10 179 L/kg之间,枯季高于洪季,随多环芳烃环数的增加而增大;K_oc值与辛醇-水分配系数K_ow之间存在较好的线性自由能关系（枯季R²＝0.82,洪季R²＝0.68）,推断出长江口滨岸颗粒物亲脂性较差,对多环芳烃的吸收能力相对较弱.长江口滨岸各采样点多环芳烃化合物的lgK_oc值均超过了经典平衡分配模型的预测值上限,多环芳烃两相分配行为不受颗粒物浓度、粒径及上覆水盐度、溶解态有机碳的控制（R²<0.1）,表现出主要受POC及非均一性混合物PSC共同影响的特点;扩展后的含PSC相的颗粒物-水相分配模型较为准确地模拟了lgK_ow<6的多环芳烃化合物野外原位分配过程.     

不同生长期翡翠贻贝(Perna viridis)体内多环芳烃富集的组织特异性研究

采用GC／MS测定了福建集美养殖区非繁殖期翡翠贻贝（Perna viridis）体内的16种多环芳烃（PAHs）,分析了不同生长期（个体大小不同）翡翠贻贝不同组织中PAHs的蓄积特征。结果表明,翡翠贻贝对PAHs的蓄积量（∑PAHs）为短生长期〉中生长期〉长生长期;外套膜〉内脏团,鳃组织中PAHs波动较大。贻贝易蓄积低环低分子量的PAHs,且随个体增大,各组织中低分子量的PAHs含量逐渐降低,高分子量的略有增加。     

土壤颗粒对焦化废水中有机物的吸附特性研究

采用GC/MS对焦化废水中有机污染物进行了分析,并通过静态试验,研究了土壤颗粒对焦化废水中有机污染物的吸附特性。结果表明,焦化废水中含有多种多环芳烃物质;焦化废水中的具不饱和键物质、苊和菲在土壤颗粒中的吸附等温线是线性的,吸附主要是分配作用的结果;土壤颗粒对焦化废水中具不饱和键物质的吸附速度基本上符合班厄姆公式形式,温度在5～45℃范围内时,对吸附及平衡浓度的影响很小。     

长江重点江段水体中多环芳烃及其衍生物的分布及健康风险

研究了长江攀枝花、宜宾、泸州、重庆、涪陵、三峡、岳阳、武汉、九江和南京共计10个重点江段枯水期和丰水期表层水中19种多环芳烃(PAHs)及其15种衍生物(SPAHs)的分布和来源,评估了长江PAHs类污染的健康风险及时空差异.结果表明,长江表层水中∑PAHs、∑SPAHs平均浓度分别为(147.3±59.8)、(73.2±29.7) ng·L^-1,检出率分别为82.9%、69.5%,其中2~3环(S)PAHs所占比例为79%.在SPAHs中,∑NPAHs(硝基取代PAHs)、∑MPAHs(甲基取代PAHs)、∑OPAHs(氧化PAHs)的平均浓度分别为(27.0±4.5)、(24.7±15.5)、(17.1±11.9) ng·L^-1.根据分子比值法及主成分分析可知,长江重点江段PAHs主要来源于生物质、化石及液体燃料燃烧,SPAHs主要来源于燃烧源和光化学转化,SPAHs及PAHs通过大气沉降汇入水体.采用毒性当量因子浓度计算对长江重点江段PAHs进行健康风险评估,结果表明在枯水期具有致癌性PAHs的∑TEQ_BaP值(苯并芘毒性当量)较高,其中岳阳、武汉江段的BaP毒性当量浓度高于我国地表水规定阈值,应当高度重视长江流域PAHs在枯水期引起的健康风险.     

Adsorption and partition of benzo(a)pyrene on sediments with different particle sizes from the Yellow River

Experiments have been carried out to study the sorption of Benzo(a)pyrene(Bap) on sediment particles from the Yellow River using a batch equilibration technique. Effects of particle size on the adsorption and partition of Bap were investigated with the particle content of 3 g/L. Several significant results were obtained from the study. (1) Isotherms of Bap could be fitted with the dual adsorption-partition model under different particle sizes, and the measured value of the adsorption and partition was in agreement with the theoretical value of the dual adsorption-partition model. (2) When the particle diameter was d ⩾ 0.025 mm, the adsorption was predominant in the sorption of Bap, which accounted for 68.7%–82.4% of the sorption. For the particles with the size of 0.007 mm⩽d<0.025 mm, the adsorption was predominant when the equilibrium concentration of Bap was 0–8.87 μg/L in the water phase; and the partition was predominant when the equilibrium concentration of Bap was higher than 8.87 μg/L in the water phase. When the particle diameter was d<0.007 mm, the partition was predominant. (3) On the point of particle size, the contribution of adsorption to sorption followed the order: “d⩾0.025 mm”>“0.007 mm ⩽d<0.025 mm” >“d<0.007 mm”. (4) The partition coefficients of Bap in solids with different particle sizes were linearly correlated with the organic content, and the K _oc of Bap was about 1.26 × 10⁵ (L/kg). Translated from Acta Scientiae Circumstantiae, 2006, 26(2): 269–274 [译自: 环境科学学报]     

多环芳烃对海洋硅藻中肋骨条藻的光毒性效应

许多生态毒理学研究尤其是对水生生物的毒性研究表明,阳光中的紫外辐射(UV)能够促进多环芳烃的生物毒性. 以长江口浮游植物群落中的常年主要优势种之一——中肋骨条藻(Skeletonema costatum)为实验材料,选择2个环的萘,3个环的菲和蒽,4个环的荧蒽和芘5种寡环多环芳烃,在实验室内比较了它们在没有UV辐射和有UV辐射下对中肋骨条藻的毒性效应. 结果表明:在没有UV照射下,萘、菲、蒽、荧蒽和芘对中肋骨条藻的72 h EC50值分别比有UV照射下时高约1.9,8.4,13.0,6.5和5.7倍,其中蒽相差的倍数最大.在没有UV照射情况下,5种多环芳烃对中肋骨条藻种群生长的抑制作用强度表现为荧蒽>芘>蒽>菲>萘;而当系统中加入UV照射后,毒性强度变为荧蒽≈蒽>芘>菲>萘,表明UV照射不仅能够促进多环芳烃对中肋骨条藻的毒性,也能够改变它们对中肋骨条藻的相对毒性.      

Emission characteristics of dioxins, furans and polycyclic aromatic hydrocarbons during fluidized-bed combustion of sewage sludge

Pre-dried sewage sludge with high sulfur content was combusted in an electrically heated lab-scale fluidized-bed incinerator. The emission characteristics of polychlorinated dibenzo-p-dioxins (PCDDs), polychlorinated dibenzofurans (PCDFs) and polycyclic aromatic hydrocarbons (PAHs) were studied. Coal and calcium oxide (CaO) were added during the sewage sludge combustion tests to optimize combustion conditions and control SO2 emission. The results indicated that the flue gases emitted during mono-combustion of sewage sludge were characterized by relatively high concentrations of SO2, NOx and organic pollutants, due to the high sulfur, nitrogen, and volatile matter content of sewage sludge. The total 16 USEPA priority PAHs and 2,3,7,8-substituted PCDD/Fs produced from sewage sludge combustion were found to be 106.14 g/m3 and 8955.93 pg/m3 in the flue gas, respectively. In the case of cocombustion with coal (msludge/mcoal = 1:1), the 16 PAHs and 2,3,7,8-substituted PCDD/Fs concentrations were markedly lower than those found during mono-combustion of sewage sludge. During co-combustion, a suppressant e ect of CaO on PCDD/Fs formation was observed.     

几种植物根亚细胞中菲的分配

以菲为多环芳烃(PAHs)代表物,采用温室水培试验方法,研究了黑麦草、苏丹草、墨西哥玉米、高羊茅、三叶草等5种植物根亚细胞中菲的分配作用.结果表明,经144h培养,随着培养液中菲平衡浓度由0.056mg·L-1增至0.39mg·L-1,黑麦草根、细胞壁、细胞器中菲的含量分别从26.85、20.01和36.19mg·kg-1增大到56.91、49.54和59.77mg·kg-1,富集系数则分别由357.14、479.49和649.25L·kg-1降低到145.92、127.04和153.26L·kg-1.黑麦草根及亚细胞组分中菲的含量大小为细胞器根细胞壁,其中细胞器中菲含量要比细胞壁高21%～163%.水中菲的起始浓度均为1mg·L-1时,144h后,供试5种植物根细胞器中菲的含量(48.64～145.2mg·kg-1)均大于细胞壁(15.86～74.49mg·L-1).5种植物根亚细胞中菲分配的比例大小顺序为细胞器细胞壁可溶部分;其中,根内46%～53%和31%～40%的菲分别分布在细胞器和细胞壁中.     

Uptake and accumulation of phenanthrene and pyrene in spiked soils by Ryegrass(Lolium perenne L.)

Phytoremediation has long been recognized as a cost-effective method for the removal of polycyclic aromatic hydrocarbons （PAHs） from soil. A study was conducted to investigate the uptake and accumulation of PAHs in root and shoot of Lolium perenne L. Pot experiments were conducted with series of concentrations of 3.31-378.37 mg/kg for phenanthrene and those of 4.22-365.38 mg/kg for pyrene in a greenhouse. The results showed that both ryegrass roots and shoots did take up PAHs from spiked soils, and generally increased with increasing concentrations of PAH in soil. Bioconcentration factors（BCFs） of phenanthrene by shoots and roots were 0.24- 4.25 and 0.17-2.12 for the same treatment. BCFs of pyrene by shoots were 0.20-1.5, except for 4.06 in 4.32 mg/kg treatment, much lower than BCFs of pyrene by roots （0.58-2.28）. BCFs of phenanthrene and pyrene tended to decrease with increasing concentrations of phenanthrene and pyrene in soil. Direct uptake and accumulation of these compounds by Lolium perenne L. was very low compared with the other loss pathways, which meant that plant-promoted microbial biodegradation might be the main contribution to plant-enhanced removal of phenanthrene and pyrene in soil. However, the presence of Lolium perenne L. significantly enhanced the removal of phenanthrene and pyrene in spiked soil. At the end of 60 d experiment, the extractable concentrations of phenanthrene and pyrene were lower in planted soil than in non-planted soil, about 83.24%-91.98% of phenanthrene and 68.53%-84.10% of pyrene were removed from soils, respectively. The results indicated that the removal of PAHs in contaminated soils was a feasible approach by using Lolium perenne L.     

PAHs降解菌的分离、鉴定及降解能力测定

以芴、菲、蒽、芘为碳源和能源筛选、分离PAHs降解菌。14株能降解利用PAHs的菌株被分离。通过HPLC分析,在含芴、菲、蒽、芘的混合培养基质中10号菌的降解能力最强。研究它的降解性能和生长情况,表明该菌在混合反应体系中培养30d后对芴、菲、蒽、芘的降解率分别为95.27、90.46、28和80%;在只含一种PAH的单反应体系中该菌对芴、菲、蒽的降解能力提高,降解率分别可达98.91、94.32和52.17%,而对芘的降解能力则降低,降解率仅为62.47%。与混合PAHs培养体系相比,在单一PAH培养体系中,细菌的对数生长期缩短1/3。经生理生化鉴定和16SrDNA序列对比分析,确定10号菌株属于假单胞菌,命名为PseudomonasspFAP10。     

安徽中北部河流沉积物的特征与多环芳烃分布

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