环境中多环芳烃(PAHs)的生物标志物的功效分析

污染物的生物监测一直是环境风险评估研究的重要内容.肝脏中谷胱甘肽硫转移酶(glutathione-S -transferase,GST)、7-乙氧基-3-异吩恶唑酮-脱乙基酶(ethoxyresorufin-O-deethylase,EROD)、DNA-加合物(DNA-adducts)和胆汁中多环芳烃代谢物(PAH m...     

A review of gas-phase chemical mechanisms commonly used in atmospheric chemistry modelling

The atmospheric chemical mechanism is an essential component of airshed models used for investigating the chemical behaviors and impacts of species. Since the first tropospheric chemical mechanism was proposed in the 1960s, various mechanisms including Master Chemical Mechanism (MCM), Carbon Bond Mechanism (CBM), Statewide Air Pollution Research Center (SAPRC) and Regional Atmospheric Chemistry Mechanism (RACM) have been developed for different research purposes. This work summarizes the development and applications of these mechanisms, introduces their compositions and lumping methods, and compares the ways the mechanisms treat radicals with box model simulations. CBM can reproduce urban pollution events with relatively low cost compared to SAPRC and RACM, whereas the chemical behaviors of radicals and the photochemical production of ozone are described in detail in RACM. The photolysis rates of some oxygenated compounds are low in SAPRC07, which may result in underestimation of radical levels. As an explicit chemical mechanism, MCM describes the chemical processes of primary pollutants and their oxidation products in detail. MCM can be used to investigate certain chemical processes; however, due to its large size, it is rarely used in regional model simulations. A box model case study showed that the chemical behavior of OH and HO₂ radicals and the production of ozone were well described by all mechanisms. CBM and SAPRC underestimated the radical levels for different chemical treatments, leading to low ozone production values in both cases. MCM and RACM are widely used in box model studies, while CBM and SAPRC are often selected in regional simulations.     

Pollution characteristics and health risk assessment of polycyclic aromatic hydrocarbons and nitrated polycyclic aromatic hydrocarbons during heating season in Beijing

Polycyclic aromatic hydrocarbons(PAHs) and their nitrated derivatives(NPAHs) attract continuous attention due to their outstanding carcinogenicity and mutagenicity. In order to investigate the diurnal variations, sources, formation mechanism, and health risk assessment of them in heating season, particulate matter(PM) were collected in Beijing urban area from December 26, 2017 to January 17, 2018. PAHs and NPAHs in PM were quantitatively analyzed via gas chromatography-mass spectrometry(GC-MS). ...     

某工业城市大气颗粒物中PAHs的粒径分布及人体呼吸系统暴露评估

为研究大气颗粒物中多环芳烃(PAHs)的粒径分布与富集特征,确定不同粒径颗粒物中PAHs在人体呼吸系统各器官内的沉积浓度,以准确评估其人体呼吸暴露风险,选择东北某钢铁工业城市,在采暖期和非采暖期按粒径对大气颗粒物进行分级采样,用高效液相色谱对样品中14种优控PAHs进行分析,并将大气颗粒物粒径分级采样技术与人体呼吸系统内部沉积模型结合进行呼吸暴露评估.结果表明,大气颗粒物中总PAHs浓度变化显著,采暖期(743. 9 ng·m~(-3))高于非采暖期(169. 0ng·m~(-3)),多数PAHs(86. 3%～89. 9%)与大气中粒径≤2. 06μm的细颗粒有关;中低分子量PAHs单体呈双峰型,峰值位于1. 07～2. 06μm和7. 04～9. 99μm.高分子量PAHs呈单峰分布,峰值位于1. 07～2. 06μm; 4环PAHs的含量占主导优势,为总PAHs浓度的40%;在采暖期和非采暖期分别有53. 3%和55. 3%的颗粒态PAHs沉积在人体呼吸系统的不同器官,分别采用人体呼吸系统沉积浓度和在颗粒物上的总浓度计算该地区人群颗粒态PAHs的终身致癌超额风险值(incremental lifetime cancer risk,R值),成人的R值在采暖期为1. 3×10-5和2. 9×10-5,非采暖期为3. 1×10-6和6. 0×10-6,儿童的R值在采暖期为1. 0×10-5和2. 3×10-5,非采暖期为2. 4×10-6和4. 8×10-6.结果表明,颗粒物粒径分布直接影响呼吸系统沉积浓度和致癌风险,将分级采样技术与呼吸系统沉降模型结合方法可有效避免对人体呼吸暴露量的过度评估.     

典型工业区土壤多环芳烃污染特征及影响因素

为完善我国典型工业区土壤多环芳烃(polycyclic aromatic hydrocarbons,PAHs)污染特征数据库,系统采集了成都市4个典型石油加工类工业区表层土壤样品,采用高效液相色谱法分析16种美国环保署优先控制PAHs的含量和组分特征.结果表明,4个工业区表层土壤(0～30 cm)中多环芳烃总含量范围为191. 2～1 604. 2μg·kg-1,平均含量(583. 6±365. 6)μg·kg-1;各工业区土壤PAHs均主要以中环PAHs和高环PAHs为主,各单体PAHs中以菲、芘、荧蒽和苯并[b]荧蒽为主要特征因子,且均存在潜在的污染风险.同时,采用数理统计方法分析土壤有机质及土壤颗粒粒径与PAHs含量的相关性,并揭示土壤PAHs赋存影响因素.结果表明,在土壤污染含量较高地块,土壤有机质是PAHs较好的吸附剂,能够在一定程度上预测土壤PAHs的迁移转化行为及土壤生态风险(PAHs致癌性);与有机质相比,土壤粒径与PAHs的相关性较低,总体表现为砂粒与PAHs含量无显著相关性,粉粒与之弱正相关,黏粒与之弱负相关.通过本研究,为此类区域的土壤修复实践或学术研究提供依据.     

生物炭负载P掺杂g-C3N4复合光催化剂制备及其对萘光催化降解机制

采用农业资源废弃物玉米秸秆为生物质原材料,双氰胺为前驱物,（NH₄）₂HPO₄为磷源,通过高温煅烧和浸渍法成功制备了可循环使用的生物炭负载P掺杂g-C₃N₄复合光催化剂,并采用X射线衍射（XRD）、红外光谱（FTIR）、扫描电子显微镜（SEM）、紫外可见漫反射（UV-vis DRS）和光致发光光谱（PL）等手段对所制备样品的化学结构、表观形貌和光学特性进行了表征.结果表明,成功将P元素引入g-C₃N₄结构中,可有效改变其能带结构,降低其光生载流子复合几率;此外,生物炭作为载体,具有较好的稳定性和特殊的光电性能,不仅有利于g-C₃N₄的光电荷分离,还可提高其对可见光的响应能力.选取多环芳烃萘作为研究对象来探究不同种类光催化剂的光催化性能及对萘的去除效率.结果表明,质量比为1：1的生物炭负载P掺杂g-C₃N₄对萘表现出了最优的光催化性能,去除率为76.41%,一级动力学反应速率常数为0.0084 min^-1,是纯g-C₃N₄的3.1倍.此外,通过自由基捕获实验提出了光催化降解萘的可能机理.     

沟塘水质及其周边浅层地下水PAHs的风险评价

为探讨农村居民区沟塘水质对周边浅层地下水的影响,在河南省某县选择典型沟塘,分别在枯水期和丰水期采集沟塘水和周边浅层地下水样品,采用高效液相色谱检测16种多环芳烃（PAHs）的含量,分别描述并比较枯丰水期PAHs的污染特征及其生态与健康风险.结果表明,枯水期沟塘水中BaP含量、∑PAHs、TEQ（BaP）含量和致癌性PAHs占比分别为0.911ng/L、29.3ng/L、1.64ng/L和28.1%,均低于丰水期;浅层地下水中各指标分别为5.37ng/L、291ng/L、12.5ng/L和25.9%,高于丰水期.枯丰水期沟塘水和浅层地下水中PAHs均主要源于生物质和煤炭燃烧.浅层地下水PAHs的含量与沟塘水具有关联性,即距离沟塘越近,PAHs含量越高,枯水期的关联性低于丰水期.饮用浅层地下水致PAHs暴露的累积非致癌风险HQ为2.21x10^-3;累积致癌风险R为1.56x10^-6,72.0%成人R大于1x10^-6,枯水期BaA、BbF和InP对成人致癌风险的贡献分别为72.1%、9.10%和4.80%.枯水期沟塘水PAHs总量为低等生态风险,丰水期为中等风险,不同沟塘其生态风险不同.纳污的C5沟塘水丰水期PAHs为高生态风险水平,BaA的贡献最大（占40.7%）;纳污和养殖的A2枯水期和C3沟塘水丰水期PAHs为中等风险2水平.综上,沟塘水PAHs与周边浅层地下水具有关联性,枯水期沟塘水PAHs总量具有低生态风险,饮用周边浅层地下水的致癌风险高于1x10^-6.     

Co-metabolic and biochar-promoted biodegradation of mixed PAHs by highly efficient microbial consortium QY1

Polycyclic aromatic hydrocarbons (PAHs), typical representatives of the persistent organic pollutants (POPs), have become ubiquitous in the environment. In this study, a novel microbial consortium QY1 that performed outstanding PAHs-degrading capacity has been enriched. The degradation characteristics of single and mixed PAHs treated with QY1 were studied, and the effect of biochar on biodegradation of mixed PAHs and the potential of biochar in PAHs-heavy metal combined pollution bioremediation were also investigated. Results showed that, in single substrate system, QY1 degraded 94.5% of 500 mg/L phenanthrene (PHE) and 17.8% of 10 mg/L pyrene (PYR) after 7 days, while in PHE-PYR mixture system, the biodegradation efficiencies of PHE (500 mg/L) and PYR (10 mg/L) reached 94.0% and 96.2%, respectively, since PHE served as co-metabolic substrate to have significantly improved PYR biodegradation. Notably, with the cooperation of biochar, the biodegradations of PHE and PYR were greatly accelerated. Further, biochar could reduce the adverse impact of heavy metals (Cd²⁺, Cu²⁺, Cr₂O₇^2?) on PYR biodegradation remarkably. The sequencing analysis revealed that Methylobacterium, Burkholderia and Stenotrophomonas were the dominant genera of QY1 in almost all treatments, indicating that these genera might play key roles in PAHs biodegradation. Overall, this study provided new insights into the efficient bioremediation of PAHs-contaminated site.     

化工园区地下水环境状况调查监测布点研究

借鉴环境风险源目标管理的理念,按照“分区、分类、分级”监测的原则,建立了化工园区地下水环境状况调查监测布点方法体系,并以某化工园区为示例展开应用研究。结果显示,该方法能对化工园区不同区域、不同类型、不同级别的地下水污染源构建差异化监测网络,解决化工园区地下水污染多元化监测布点问题,可为化工园区地下水环境状况调查监测布点方案的拟定或优化调整提供工作参考。     

承德市PM2.5中多环芳烃的季节分布特征、来源解析及健康风险评价

为研究承德市PM_2.5中多环芳烃（PAHs）的季度变化特征和污染来源,于2019年的1、 4、 7和10月采集PM_2.5样品,采用气相色谱-质谱联用仪（GC-MS）测定了16种PAHs的浓度,并利用时序变动、特征比值和正定矩阵因子模型（PMF）的方法,分析了各季节PAHs的浓度变动、组分特征和潜在污染源.此外,为评价PAHs对健康风险的影响,采用BaP毒性当量法(BaP_Teq)及增量终生致癌风险（ILCR）模型,并结合PAHs数据和PMF结果进行分析.结果表明,采样期间承德市PM_2.5中■的变化范围为2.7～246.4 ng·m^-3,呈现（136.8±52.1）ng·m^-3（冬季）>（70.3±36.7）ng·m^-3（秋季）>（24.7±17.4）ng·m^-3（春季）>（13.7±9.4）ng·m^-3（夏季）的显著季节特征.不同环数PAHs的浓度占总浓度的占比中,5～6环的...