帕米尔高原东部PM10输送路径及潜在源分析

基于HYSPLIT后向轨迹模式和NCEP的GDAS数据（2019年3月~2020年2月）,对抵达帕米尔高原东部的48h后向气团轨迹按季节聚类,其PM₁₀和PM_2.5年均值分别为（29.4±16.4）,（9.3±5.1）μg/m³,大气颗粒物以PM₁₀为主,结合同期PM₁₀浓度数据,分析不同路径对帕米尔高原东部PM₁₀聚集的贡献,并利用潜在源贡献因子法（PSCF）和浓度权重轨迹法（CWT）,揭示研究期间帕米尔高原东部不同季节PM₁₀的潜在源分布及其贡献水平.结果表明：帕米尔高原东部PM₁₀输送路径的季节特征明显,春季来自中亚的西风气流对应PM₁₀高值,夏季来自中国新疆西部的气流也对应较高PM₁₀值,秋季各轨迹对应PM₁₀值相当,冬季来自南亚方向气流对应PM₁₀高值.PM₁₀春季贡献源区主要位于中国新疆西部、阿富汗东北部、巴基斯坦东北部、塔吉克斯坦中部及东部地区,夏季主要位于中国新疆西部喀什与和田北部地区,秋季主要位于土库曼斯坦东部、乌兹别克斯坦东南部、巴基斯坦北部、阿富汗北部与塔吉克斯坦南部接壤地区,冬季主要位于巴基斯坦东北部、印度北部以及阿富汗北部.     

Comparison of light absorption and oxidative potential of biodiesel/diesel and chemicals/diesel blends soot particles

Soot particles,mainly coming from fuel combustion,affect climate forcing through absorbing light and also result in adverse human health outcomes.Though biodiesel or additives blending with diesel was considered environmentally friendly,the understanding on absorbing and oxidative capacity of soot emitted from them are still unclear.The watersoluble organic carbon(WSOC) content,surface chemical structure,light absorption and oxidative potential(OP~(DTT)) of soot from biodiesel/diesel and chemicals/diesel blends were investigated utilizing total organic carbon analyzer,X-ray photoelectron spectrometer,ultraviolet–visible spectrophotometry and dithiothreitol(DTT) assay.The differences and correlations between soot properties were statistically analyzed.Chemicals/diesel blends soot owned significantly higher WSOC content,ratio of mass absorbing efficiency(MAE) in250 and 365 nm(E_2/E_3),OP~(DTT),and higher surface carbonyl content.Coconut biodiesel/diesel blends soot contained evidently higher aromatic carbon–oxygen single bond(Ar_C–O)content,and higher MAE365.The individual comparison of biodiesel/diesel blends showed20% coconut biodiesel blend owned the lowest WSOC,E_2/E_3 and OP~(DTT),while highest Ar_C–O and MAE365,representing strongest absorbing properties.Association analysis showed OP~(DTT)was significantly positively correlated with WSOC.Further,the evident negative correlation between MAE365 and OP~(DTT) was observed.Our results showed coconut biodiesel/diesel blends soot induced lower levels of oxidative potential,whereas absorption of light was higher,which have far reaching consequences on climate forcing.Therefore,it is important to evaluate the balance point between light-absorbing properties and oxidative potential,under the wide use of biodiesel.     

Environmental impact and health risk assessment of volatile organic compound emissions during different seasons in Beijing

Volatile organic compounds (VOCs) are major contributors to air pollution. Based on the emission characteristics of 99 VOCs that daily measured at 10 am in winter from 15 December 2015 to 17 January 2016 and in summer from 21 July to 25 August 2016 in Beijing, the environmental impact and health risk of VOC were assessed. In the winter polluted days, the secondary organic aerosol formation potential (SOAP) of VOC (199.70 ± 15.05 μg/m³) was significantly higher than that on other days. And aromatics were the primary contributor (98.03%) to the SOAP during the observation period. Additionally, the result of the ozone formation potential (OFP) showed that ethylene contributed the most to OFP in winter (26.00% and 27.64% on the normal and polluted days). In summer, however, acetaldehyde was the primary contributor to OFP (22.00% and 21.61% on the normal and polluted days). Simultaneously, study showed that hazard ratios and lifetime cancer risk values of acrolein, chloroform, benzene, 1,2-dichloroethane, acetaldehyde and 1,3-butadiene exceeded the thresholds established by USEPA, thereby presenting a health risk to the residents. Besides, the ratio of toluene-to-benzene indicated that vehicle exhausts were the main source of VOC pollution in Beijing. The ratio of m-/p-xylene-to-ethylbenzene demonstrated that there were more prominent atmospheric photochemical reactions in summer than that in winter. Finally, according to the potential source contribution function (PSCF) results, compared with local pollution sources, the spread of pollution from long-distance VOCs had a greater impact on Beijing.     

产业转移视角下京津冀石化产业碳排放因素分解与减排潜力分析

石化产业是我国经济的支柱性产业,但其大量的碳排放却给环境造成严重负担,因此提倡石化产业低碳发展能有效推动京津冀区域经济与环境绿色均衡发展.基于产业转移视角,分析2007-2016年京津冀区域石化产业碳排放量现状;运用对数平均迪式分解（Logarithmic Mean Divisia Index,LMDI）法分解并分析京津冀区域石化产业碳排放量影响因素在三地的作用效果,进而借助产业竞争力系数佐证碳排放量影响因素作用效果在区域间的关联性;最后通过合理调整京津冀区域石化产业能源结构,将未调整和调整后的能源结构类型分别设置为基准情境和低碳情境,利用SPSS拟合最优曲线来预测2017-2030年京津冀区域石化产业减排潜力.结果表明:①2007-2016年京津冀区域石化产业碳排放量增加386.79×104 t,碳排放强度由0.77 t/（104元）降至0.31 t/（104元）.②2007-2016年,能源强度因素使京津冀区域石化产业碳排放量减少13 663.77×104 t,其贡献率高达148.38%;人均GDP因素促使石化产业碳排放量增加12 327.10×104 t,贡献率达110.69%.③对于石化产业竞争力系数,北京市由0.03降至-0.02,为三地石化产业转出地;河北省由-0.14增至0.16,为转入地.④在低碳情境下,2020年、2030年京津冀区域石化产业碳排放量分别比基准情境减少502.84×104、528.95×104 t,碳排放强度分别降至0.19、0.17 t/（104元）,均达到发展目标的要求.研究显示,2007-2016年京津冀区域石化产业碳排放量逐年上升,承受巨大减排压力,该区域可以通过调整石化产业能源结构来挖掘碳减排潜力,推动石化产业绿色发展.      

Characteristics and ozone formation potential of volatile organic compounds in emissions from a typical Chinese coking plant

Coking industry is an important volatile organic compounds (VOCs) emission source in China, however, detailed information on VOCs emissions is lacking. Therefore, we selected a typical mechanized coking plant and collected air samples according to the Emission Standard of Pollutants for Coking Chemical Industry (GB16171-2012). Using gas chromatography-mass spectrometry method, we analyzed the VOCs in the air samples, and applied maximum increment reactivity (MIR) rule to estimate ozone formation potential (OFP) of the VOCs emitted from the coke production. More than 90 VOCs species were detected from the coking plant, including alkanes, alkenes, alkynes, aromatic hydrocarbons, halogenated hydrocarbons and oxygenated VOCs. The concentrations of VOCs (ρ(VOCs)) generated at different stages of the coking process are significantly different. ρ(VOCs) from coke oven chimney had the highest concentration (87.1 mg/m³), followed by coke pushing (4.0 mg/m³), coal charging (3.3 mg/m³) and coke oven tops (1.1 mg/m³). VOCs species emitted from the coke production processes were dominated by alkanes and alkenes, but the composition proportions were different at the different stages. Alkenes were the most abundant emission species in flue gases of the coke oven chimney accounting for up to 66% of the total VOCs, while the VOCs emissions from coke pushing and coal charging were dominated by alkanes (36% and 42%, respectively), and the alkanes and alkenes emitted from coke oven top were similar (31% and 29%, respectively). Based on above results, reduction of VOCs emissions from coke oven chimney flue gases is suggested to be an effective measure, especially for alkenes.     

Characteristics of atmospheric volatile organic compounds in urban area of Beijing: Variations, photochemical reactivity and source apportionment

Atmospheric volatile organic compounds (VOCs) were observed by an on-line gas chromatography-flame ionization detector monitoring system from November 2016 to August 2017 in Beijing. The average concentrations were winter (40.27 ± 25.25 μg/m³) > autumn (34.25 ± 19.90 µg/m³) > summer (32.53 ± 17.39 µg/m³) > spring (24.72 ± 17.22 µg/m³). Although benzene (15.70%), propane (11.02%), ethane (9.32%) and n-butane (6.77%) were the most abundant species, ethylene (14.07%) and propene (11.20%) were the key reactive species to ozone formation potential (OFP), and benzene, toluene, ethylbenzene, m-xylene + p-xylene and o-xylene (54.13%) were the most reactive species to secondary organic aerosol formation potential (SOAFP). The diurnal and seasonal variations indicated that diesel vehicle emission during early morning, gasoline vehicle emission at the traffic rush hours and coal burning during the heating period might be important sources. Five major sources were further identified by positive matrix factorization (PMF). The vehicle exhaust (gasoline exhaust and diesel exhaust) was found to be contributed most to atmospheric VOCs, with 43.59%, 41.91%, 50.45% and 43.91%, respectively in spring, summer, autumn and winter; while solvent usage contributed least, with 11.10%, 7.13%, 14.00% and 19.87%, respectively. Biogenic emission sources (13.11%) were only identified in summer. However, both vehicle exhaust and solvent usage were identified to be the key sources considering contributions to the OFP and SOAFP. Besides, the contributions of combustion during heating period and gasoline evaporation source during warm seasons to OFP and SOAFP should not be overlooked.     

地下水潜在污染源危害性评价方法研究

地下水污染源危害性评价对地下水资源保护及地下水污染防控区划具有重要意义,然而现有区域尺度地下水污染源荷载危害性评价弱化了点源污染复合强度对地下水的影响.因此,为更准确地进行区域地下水潜在污染源危害性评价,引入污染复合强度要素.选取工业源、农业源、生活源、地表排污河、垃圾场和加油站为研究对象,构建以污染源种类、污染物排放量、污染源释放可能性、缓冲区半径和污染复合强度为指标的综合评价模型,采用层次分析法确定各类污染源权重,基于ArcGIS 10.2软件对沧州市进行地下水综合潜在污染源荷载危害性评价.结果表明:Ⅳ、Ⅴ级风险区面积为5 560.0 km2,占总面积的41.6%,主要位于沧州市中部、北部地区,其危害性受工业源影响最大;Ⅰ、Ⅱ级风险区面积为3 303.4 km2,占总面积的25.2%,主要位于沧州市东部地区.研究显示,该评价方法强化了点源污染复合强度对地下水危害性的影响,可为区域地下水潜在污染源危害性评价提供参考,对地下水资源保护及污染防控区划具有重要意义.      

川南自贡市大气颗粒物污染特征及传输路径与潜在源分析

川南自贡市大气颗粒物污染比较严重, 2015～2018年PM_(10)和PM_(2.5)平均浓度分别为(95.42±9.53)μg·m~(-3)和(65.95±6.98)μg·m~(-3),并有明显的下降趋势,冬季PM_(10)和PM_(2.5)浓度远高于其它季节, 1月平均浓度最高,分别为(138.08±52.29)μg·m~(-3)和(108.50±18.05)μg·m~(-3),夏季平均浓度最低.PM_(2.5)与PM_(10)的平均比值为69.12%,冬季比值约为夏季的1.17倍,空气污染以PM_(2.5)为主.采用拉格朗日混合单粒子轨迹模型(HYSPLIT)和全球资料同化系统的GDAS气象数据,对自贡市细颗粒物(PM_(2.5))浓度和逐日72 h后向轨迹进行计算和聚类研究,利用潜在源贡献分析法(PSCF)和浓度权重轨迹分析法(CWT),探讨不同季节影响自贡市PM_(2.5)浓度的潜在源区以及不同源区的污染贡献.结果表明,自贡市近地面四季多受东南风、偏西风和西北风控制,高浓度PM_(2.5)多出现在0～2 m·s~(-1)的低风速区;不同季节、不同输送路径对自贡PM_(2.5)污染影响的差异显著,春季主要受到来自偏西和偏北方向短距离输送气流的影响,夏季污染轨迹主要来自短距离输送的东南气流,秋季主要受来自资阳,经遂宁、重庆和内江的短距离输送气流的影响,冬季除受到资阳、遂宁和内江等周边城市的影响外,还受到来自西藏中部的远距离输送气流影响;除夏季外,自贡市潜在源区主要位于重庆西部与川南交界区域,冬季的主要贡献区范围最广、贡献程度最大,夏季潜在源区范围最小且贡献程度最弱.     

阳泉市区夏季挥发性有机物污染特征、来源解析及其环境影响

采集阳泉市区夏季3个监测点的环境空气样品,利用气相色谱-质谱/氢火焰离子化检测器(GC-MSD/FID)测定了挥发性有机物(VOCs)的组成,研究了其浓度特征,运用特征比值法和正定矩阵因子分析模型(PMF)解析了VOCs来源,评估了VOCs对O_3和二次有机气溶胶(SOA)生成的影响.结果表明,阳泉市区VOCs平均总浓度为(82.1±22.7)μg·m~(-3),其中烷烃浓度占比最大(51.8%),其次是芳香烃(17.8%)和烯烃(8.0%),炔烃浓度占比最小(3.8%). VOCs呈现双峰的变化特征,分别于08:00～10:00和18:00～20:00出现峰值,在12:00～14:00出现谷值.苯/甲苯和异戊烷/正戊烷的均值分别为2.1±1.3和1.7±0.6,表明环境空气VOCs可能受燃煤排放和机动车排放的双重影响. PMF解析出VOCs来源分别为燃煤源(34.9%)、机动车排放源(18.2%)、汽油挥发源(15.2%)、工业排放源(13.6%)、植物排放源(9.2%)和溶剂使用源(9.0%). VOCs臭氧生成潜势(OFP)均值为156.6μg·m~(-3),烯烃贡献最大,二次有机气溶胶生成潜势(SOA_p)均值为68.7μg·m~(-3),芳香烃的贡献达到93.4%.总之,燃煤排放对VOCs的贡献较高,因此,控制燃煤源排放是阳泉市区VOCs管控重点,需加快矸石山治理和能源结构调整,同时机动车排放源、汽油挥发源和工业排放源的管控也不容忽视.     

长距离供水系统中消毒副产物分布特征及二次加氯的影响

供水管网覆盖区域大,导致出厂消毒剂量不足以维持管网末梢余氯量,需进行途中二次投氯.以H市供水管网为目标,通过均匀布点采样分析,考察二次加氯消毒型管网中消毒副产物(disinfection by-products,DBPs)的分布特征.结果表明,管网中检出DBPs包括三氯甲烷(TCM)、一溴二氯甲烷(BDCM)、二溴一氯甲烷(DBCM)、三溴甲烷(TBM)、二氯乙酸(DCAA)、三氯乙酸(TCAA)、二氯乙腈(DCAN)、溴氯乙腈(BCAN)和三氯硝基甲烷(TCNM)等,所检水样中DBPs浓度均低于《生活饮用水卫生标准》(GB 5749-2006)规定的标准限值.二次加氯前检出质量浓度(以平均值±偏差表示)分别为:(8.08±3.34)、(9.77±2.91)、(7.38±4.82)、(2.65±2.02)、(2.95±3.26)、(6.02±6.06)、(3.13±2.48)、(1.61±2.05)和(0.15±0.10)μg·L~(-1).二次加氯后检出质量浓度分别为:(10.30±4.55)、(11.73±3.60)、(8.23±5.22)、(2.95±2.45)、(3.29±3.60)、(8.15±7.58)、(3.31±2.61)、(1.33±2.04)和(0.12±0.06)μg·L~(-1).二次加氯后DBPs含量相较于出厂水至二次加氯点呈明显上升趋势,三卤甲烷(THMs)和卤乙酸(HAAs)分别比前段管网含量升高6.32%～26.60%和5.32%～42.71%.此外,原水水质和季节变化对DBPs的形成有一定影响,夏季DBPs的水平普遍高于春季或秋季.出厂水及管网水DBPs生成势分析表明,H市供水系统中DBPs可能存在超标风险,后续需考虑进一步优化处理工艺以保障供水水质.