南京冬季市区和郊区气溶胶中PAHs浓度的昼夜特征及粒径分布

为了研究南京市区与郊区气溶胶中多环芳烃(PAHs)污染状况和分布特征,利用气-质联用仪(GC-MS)分析了2010年1月1～10日日间和夜间分别在南京大学和南京信息工程大学采集的气溶胶样品,得到南京市区与郊区17种PAHs浓度,总浓度分别为41.36～220.35 ng.m-3和45.10～200.86 ng.m-3,其中约66%～67%分布于细粒子(Dp≤2.1μm)中.研究发现,南京市区和郊区气溶胶中PAH总浓度均处于较高的水平;但两者昼夜变化趋势不同,即市区PAH总浓度日间高于夜间,郊区PAH总浓度日间低于夜间.主导风向的改变和高压天气系统对PAH浓度变化影响较大;在市区其影响主要表现在细粒子部分,而郊区主要表现在粗粒子部分.市区和郊区不同环数的PAHs粒径分布不同;2～3环PAHs,郊区含量高于市区;而4～6环PAHs,市区含量高于郊区.高环数(4～6环)PAHs在粗模态出现较大浓度峰可能是由于南京地区粗模态气溶胶中碳含量较高.市区和郊区相似的特征比值说明两者的PAHs具有相同污染来源,主要为生物质及煤的燃烧和汽车尾气,表明南京市区PAHs受到郊区工业源排放影响较大.     

西安市地表灰尘中多环芳烃分布特征与来源解析

采集了西安市地表灰尘样品58个,利用GC-FID对其中16种优控多环芳烃(PAHs)进行含量分析,在此基础上研究了其分布特征与环境来源.结果表明,西安市地表灰尘中单体PAH的含量范围为14.69~6 370.48μg·kg~(-1);16种PAHs总量(Σ_(16)PAHs)范围为5 039.67~47 738.50μg·kg~(-1),平均值为13 845.82μg·kg~(-1).与国内外其他城市比较发现,西安市地表灰尘中PAHs的含量相对较高.地表灰尘中PAHs主要由4环以上的高分子量PAHs构成,7种致癌芳烃(Σ_7CPAHs)平均占Σ16PAHs的46.08%.地表灰尘中Σ_(16)PAHs的平均含量在工业区最高,文教区、交通区和商业交通混合区含量次之,住宅区和公园较低.地表灰尘中Σ_(16)PAHs平均含量沿主城区-二环-三环由内向外呈增加趋势.地表灰尘中Σ16PAHs在东郊和西郊工业区、南郊和北二环重交通区相对较高,主城区、北郊和城市东南部较低.比值法、聚类分析和主成分分析结果表明,西安市地表灰尘中PAHs主要来源于化石燃料和煤的燃烧,其中柴油燃烧和汽油燃烧的方差贡献率分别为36.07%和32.31%,煤燃烧方差贡献率为23.40%.     

Removal of polycyclic aromatic hydrocarbons from aqueous solution by raw and modified plant residue materials as biosorbents

Removal of polycyclic aromatic hydrocarbons （PAHs）, e.g., naphthalene, acenaphthene, phenanthrene and pyrene, from aqueous solution by raw and modified plant residues was investigated to develop low cost biosorbents for organic pollutant abatement. Bamboo wood, pine wood, pine needles and pine bark were selected as plant residues, and acid hydrolysis was used as an easily modification method. The raw and modified biosorbents were characterized by elemental analysis, Fourier transform infrared spectroscopy and scanning electron microscopy. The sorption isotherms of PAHs to raw biosorbents were apparently linear, and were dominated by a partitioning process. In comparison, the isotherms of the hydrolyzed biosorbents displayed nonlinearity, which was controlled by partitioning and the specific interaction mechanism. The sorpfion kinetic curves of PAHs to the raw and modified plant residues fit well with the pseudo second-order kinetics model. The sorption rates were faster for the raw biosorbents than the corresponding hydrolyzed biosorbents, which was attributed to the latter having more condensed domains （i.e., exposed aromatic core）. By the consumption of the amorphous cellulose component under acid hydrolysis, the sorption capability of the hydrolyzed biosorbents was notably enhanced, i.e., 6-18 fold for phenanthrene, 6-8 fold for naphthalene and pyrene and 5-8 fold for acenaphthene. The sorpfion coefficients （Kd） were negatively correlated with the polarity index [（O＋N）/C], and positively correlated with the aromaticity of the biosorbents. For a given biosorbent, a positive linear correlation between logKoc and logKow for different PAHs was observed. Interestingly, the linear plots of logKoc-logKow were parallel for different biosorbents. These observations suggest that the raw and modified plant residues have great potential as biosorbents to remove PAHs from wastewater.     

佛山高明河水环境多环芳烃的分布特征与通量研究

利用液液萃取法和气相色谱-质谱方法对佛山境内高明河水环境多环芳烃（PAHs）进行了测定,并对PAHs的分布特征与通量进行了初步研究.结果表明高明河水环境中16种优控PAHs的浓度范围在41.6～375.6 ng/l之间,从上游到下游总体呈递增的趋势,其下游浓度偏高可能与荷城街道较为密集的工业和人口分布有关.高明河水环境PAHs的总含量高于欧美一些低污染水域,但低于国内一些主要河流.高明河PAHs年通量约为333.8 kg.     

植物根系质外体溶液的提取方法研究:以多环芳烃为例

根系质外体溶液中多环芳烃(PAHs)的分析对于阐明植物根系PAHs吸收运移机制及阻控意义重大.然而,迄今鲜有便捷成熟的植物根系质外体溶液提取方法的报道.为此,本研究以小麦为材料,菲为PAHs的代表,探究了植物根系质外体溶液的真空渗透离心提取方法.结果表明,小麦根系质外体菲提取量随真空度、真空时间、离心速率、离心时间的增加而增大;小麦根系质外体六磷酸葡萄糖脱氢酶(G6PDH)活性随真空度、真空时间、离心速率、离心时间的增加而升高.依据质外体溶液受原生质污染程度小于1%且尽量提取完全的原则,真空渗透离心提取法的最佳真空度为70 k Pa,最佳真空时间为10 min,最佳离心速率为3 068 r·min-1,最佳离心时间为15 min.研究结果可为污染物的植物根系质外体运输研究提供有效、简便的方法支撑.     

一种简便高效的土壤石油烃提取方法的建立

通过开展单因子实验与正交实验,考察不同参数下超声萃取法对土壤中总石油烃(TPH)的提取效率,并对比了超声萃取法、超声-索氏萃取法及传统索氏萃取法对不同原油污染土壤的提取效果。结果表明:超声萃取法的最优工作参数为20 m L二氯甲烷,超声10 min,4000 r/min离心10 min,萃取4次。3种提取方法中,超声萃取法对石油烃平均回收率最高,为100.95%,而传统的索氏萃取法最低,仅为94.54%。可见,超声萃取法操作简单,效率高,可广泛用于土壤中总石油烃含量的提取测定。     

Biodegradation of polycyclic aromatic hydrocarbons (PAHs) by fungal enzymes: A review

Polycyclic aromatic hydrocarbons (PAHs) are a large group of chemicals. They represent an important concern due to their widespread distribution in the environment, their resistance to biodegradation, their potential to bioaccumulate and their harmful effects. Several pilot treatments have been implemented to prevent economic consequences and deterioration of soil and water quality. As a promising option, fungal enzymes are regarded as a powerful choice for degradation of PAHs. Phanerochaete chrysosporium, Pleurotus ostreatus and Bjerkandera adusta are most commonly used for the degradation of such compounds due to their production of ligninolytic enzymes such as lignin peroxidase, manganese peroxidase and laccase. The rate of biodegradation depends on many culture conditions, such as temperature, oxygen, accessibility of nutrients and agitated or shallow culture. Moreover, the addition of biosurfactants can strongly modify the enzyme activity. The removal of PAHs is dependent on the ionization potential. The study of the kinetics is not completely comprehended, and it becomes morem hallenging when fungi are applied for bioremediation. Degradation studies in soil are much more complicated than liquid cultures because of the heterogeneity of soil, thus, many factors should be considered when studying soil bioremediation, such as desorption and bioavailability of PAHs. Different degradation pathways can be suggested. The peroxidases are heme-containing enzymes having common catalytic cycles. One molecule of hydrogen peroxide oxidizes the resting enzyme withdrawing two electrons. Subsequently, the peroxidase is reduced back in two steps of one electron oxidation. Laccases are copper-containing oxidases. They reduce molecular oxygen to water and oxidize phenolic compounds.     

多环芳烃在冬小麦体内的吸收与转运及富集研究进展

多年来以煤炭为主的能源消费结构和经济社会持续发展,导致我国PAHs(多环芳烃)排放量居高不下,直接造成土壤和大气PAHs严重污染.为了探明PAHs在冬小麦体内的积累过程和调控机制,在系统分析PAHs在冬小麦体内的吸收、转运和富集的基础上,重点阐述了冬小麦PAHs根系吸收和叶面吸收影响因素方面的最新研究进展.研究发现:① 小麦根系对PAHs的吸收包括主动吸收和被动吸收两种方式,其中主动吸收是一个载体协助、消耗能量、PAHs与H+共运的过程;被动吸收除了在高等植物中普遍存在的简单扩散外,水-甘油通道也参与了该过程. ② PAHs通过气态、颗粒态沉降到小麦叶面角质层或直接通过气孔进入叶片. ③ 影响PAHs根系和叶面吸收的主要因素包括PAHs理化性质、植物生理状况、环境因素等. ④ 小麦根系吸收的PAHs可以向地上部转运,并且与辛醇-水分配系数(K_OW)、蒸腾速率、土壤中氮的形态和浓度有关.主要问题:① 对于小麦叶片吸收的PAHs向基运输机理有待进一步研究. ② 农田生态系统中冬小麦往往遭受土壤及大气双重污染,根系吸收及叶面吸收分别对其体内积累PAHs的贡献尚不清楚.因此,需关注韧皮部、木质部在PAHs转运中所起的作用;利用同位素示踪、双光子激发显微镜等先进技术观察和跟踪PAHs如何进入小麦以及在小麦叶中的转移和分布,阐明PAHs叶面吸收的微观机理;注重大田试验研究,为揭示冬小麦对PAHs的吸收、积累及调控机理,同时也为有机污染地区生产安全农产品提供重要依据.      

河南某市驾校地表灰尘多环芳烃组成、来源与健康风险

采集河南省某市29所驾校的地表灰尘样品,应用气相色谱-质谱联用仪(GC-MS)测定样品中16种优控PAHs含量,用终生致癌风险增量模型(ILCR)评价灰尘PAHs不同暴露情景下(情景1、2、3分别为驾校工作5 a、10 a和20 a)的健康风险,用比值法、成分谱法和主成分因子载荷法揭示PAHs来源.结果表明,驾校灰尘ΣPAHs含量在198.21~3 400.89μg·kg-1之间,平均908.72μg·kg-1.单体PAHs含量较高的是萘、菲、蒽、荧蒽,含量最低的是二苯并[a,h]蒽,低环PAHs占ΣPAHs的55.79%,高环占44.21%.3种情景下的平均健康风险为情景3(3.71×10-7)情景2(1.85×10-7)情景1(9.27×10-8),只有一个驾校(J11)在情景3存在潜在健康风险,其他情景下均无风险.皮肤接触灰尘是最主要的PAHs暴露途径,其占总风险的64.21%;其次是误食途径,占总风险的33.04%;吸入途径可忽略不计.驾校灰尘PAHs主要来源为化石燃料不完全燃烧源和混合源,农田区驾校灰尘PAHs的柴油/天然气动力车排放源、燃煤源和汽油车排放源贡献率分别为56.44%、26.55%和17.01%,工业区驾校混合源、汽油车和炼焦/燃煤排放源贡献率分别为76.26%、22.85%和0.89%,混合区驾校燃煤源、天然气/柴油动力车排放源和汽油车排放源的贡献率分别为45.57%、45.41%和9.02%.灰尘PAHs含量及健康风险与其周边环境、前期土地利用状况密切相关.     

岩溶地下河水中多环芳烃、脂肪酸分布特征及来源分析

为探究重庆青木关岩溶地下河水中多环芳烃(PAHs)和脂肪酸的含量组成、分布特征、来源及污染水平,2013年雨季和旱季分别于地下河中进行水样采集,并利用气相色谱-质谱联用仪(GC-MS)对水样中PAHs和脂肪酸的组分进行定量分析.结果表明,青木关地下河水中PAHs和脂肪酸的含量范围分别为77.3~702 ng·L~(-1)和3 302~45 254 ng·L~(-1).组成上,PAHs以2~3环为主,其比例高于90%,脂肪酸碳数范围为C10~C28,以饱和直链脂肪酸为主,其次为单不饱和脂肪酸.分布特征上,雨季:地下河水中各采样点PAHs的含量差异较小,脂肪酸的含量在入口、出露处和出口呈现依次降低的趋势,其中出露处和出口脂肪酸的含量较为接近;旱季:地下河水中PAHs含量在入口、出露处和出口呈现先降后升的趋势,脂肪酸含量在各采样点较为接近.总体上,地下河水中PAHs和脂肪酸的含量都表现为雨季显著高于旱季.来源分析表明,青木关地下河水中PAHs主要来源于该河流域煤和木材、农作物秸秆等生物质的燃烧;脂肪酸主要来自该河流域内硅藻、绿藻等水生藻类和细菌,其中以水生藻类的贡献占主导.地下河水受到PAHs中轻度污染,相对于旱季,雨季污染更严重.