排序方式: 共有36条查询结果,搜索用时 31 毫秒
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Zerovalent iron (ZVI) abiotically degrades several chlorinated aliphatic hydrocarbons (CAHs) via reductive dechlorination, which offers perspectives for in situ groundwater remediation applications. The difference in reactivity between ZVI particles is often linked with their specific surface area. However, other parameters may influence the reactivity as well. Earlier, we reported for a set of microscale zerovalent iron (mZVI) particles the disappearance kinetic of different CAHs which were collected under consistent experimental conditions. In the present study, these kinetic data were correlated with the carbon, oxygen and sulfur content of mZVI particles. It was confirmed that not only the specific surface area affects the disappearance kinetic of CAHs, but also the chemical composition of the mZVI particles. The chemical composition, in addition, influences CAHs removal mechanism inducing sorption onto mZVI particles instead of dechlorination. Generally, high disappearance kinetic of CAHs was observed for particles containing less oxygen. A high carbon content, on the other hand, induced nonreactive sorption of the contaminants on the mZVI particles. To obtain efficient remediation of CAHs by mZVI particles, this study suggested that the carbon and oxygen content should not exceed 0.5% and 1% respectively. Finally, the efficiency of the mZVI particles may be improved to some extent by enriching them with sulfur. However, the impact of sulfur content on the reactivity of mZVI particles is less pronounced than that of the carbon and oxygen content. 相似文献
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镇江城市径流颗粒粒径分布及其与污染物的关系 总被引:12,自引:2,他引:10
为了解城市中不同粒径颗粒物对于径流中污染物的影响,2006年3月在镇江城市不同功能区地表采集了沉积物样品和径流样品,分析了颗粒物的粒径分布和污染物浓度.结果表明,晴天条件下道路沉积物主要由粒径<250μm的颗粒组成;降雨初期主要为<5μm的颗粒物随径流迁移,随降雨历时的延长较大颗粒开始随径流迁移,降雨期间随地表径流迁移主要为小于150μm的颗粒物,特别是5~40μm粒径段的颗粒要特别予以关注;同时污染物浓度也由降雨初期的高浓度逐渐下降并趋于稳定.明确了径流中污染物的主要输出形态,并通过分析不同降雨历时污染物与固体悬浮物和颗粒粒径的相关性探明了径流污染物形态输出的原因,从而为城市非点源污染的管理以及控制方法的选择提供科学依据. 相似文献
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大气可吸入颗粒物研究进展 总被引:24,自引:0,他引:24
简述了国内外有关大气颗粒物中的可吸入颗粒物 (空气动力学直径小于或等于 10 μm)的研究进展 ,主要围绕可吸入颗粒物的基本特性、可吸入颗粒物与健康的关系、可吸入颗粒物的源解析 ,对其研究动向进行阐述。 相似文献
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重庆大气可吸入颗粒物中多环芳烃的分析测定 总被引:4,自引:0,他引:4
本文报告了重庆大气可吸入颗粒物(IP)中多环芳烃(PAH)的分析测定方法和结果.用GC-MS定性和定量分析了重庆IP中的PAH;研究了IP中PAH的种类和分布情况;确认重庆IP中存在甲基多环芳烃(MePAH)、约占33%;颗粒大小分布表明,约有98%PAH存在于小于3μm的颗粒中. 相似文献
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重庆城区大气颗粒物的元素、离子及物相组成研究 总被引:2,自引:0,他引:2
采用X-射线能谱(EDX),傅立叶红外光谱(FT-IR),X-射线衍射(XRI)对重庆市区大气颗粒污染物的元素组成,离子,物相组成进行顾研究,EDX检出了S,Cl,K,Ca,Ti,Cr,Mn,Fe,Cu,Se,Sr,Zr,Rb,Ga,Hg,Zn,Ni元素,FT-IR光谱发现主要存在SO4^2-,NH4^ 和NO3^-,XRD结果表明存在CaSO4.2H2O,α-SiO2,(NH4)2Ca(SO4)2.2H2O,(NH4)2SO4等4个主要物相以及Fe3O4,CaCO3等物相,初步讨论了重庆大气颗粒物的污染来源及其时间,空间分布。 相似文献
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Lu Ao Wenjun Liu Yang Qiao Cuiping Li Xiaomao Wang 《Frontiers of Environmental Science & Engineering》2018,12(6):9
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文章利用2016~2017年冬季沈阳地区气象数据和环境空气污染物浓度数据,综合分析沈阳地区冬季环境空气污染特征,分析颗粒物输送路径以及潜在源区贡献情况。结果表明,沈阳地区冬季污染时段内PM2.5是主要污染物,PM2.5平均浓度达到149μg/m^3,最大值达到273μg/m^3。沈阳地区环境空气颗粒物除来源于本地排放外,还主要受到内蒙古东北部和京津冀北部2个方向传输影响,内蒙古东北部方向传输气量约占总气量的70%。潜在源区分析表明,辽宁中西部、内蒙古东北部及京津冀北部是沈阳地区环境空气颗粒物潜在源区。浓度权重轨迹分析表明,辽宁大部、内蒙古东北部、京津冀北部和山东局部地区对沈阳地区的颗粒物浓度贡献较大,PM2.5修正后的浓度权重值WCWT>50μg/m^3,PM10的WCWT值>100μg/m^3。 相似文献
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Wilhelm Hoeflinger 《中国人口.资源与环境(英文版)》2010,8(4)
The characteristics of fine particulate pollution(PM10and PM25)were measured at urban and suburban sites in Jinan during the 2008-2009 heating and non-heating seasons.The results showed that PM10 and PM2.5 pollution was quite serious,and PM mass concentration was higher during the heating season than the non-heating season.PM was the highest in the chemical factory and lowest in the development zone.The mass concentrations of PM10 and PM2.5 were linearly related,and the mass concentration ratio of PM2.5/PM10 was up to 0.59 in urban areas.PM pollution in Jinan was related to local meteorological factors: PM2.5 mass concentration and humidity were positively correlated,and PM2.5mass concentration was negatively correlated with both click on the temperature and wind speed,although wind speed varied more. 相似文献
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Abstract The characteristics of fine particulate pollution (PM10 and PM2.5) were measured at urban and suburban sites in Jinan during the 2008–2009 heating and non-heating seasons. The results showed that PM10 and PM2.5 pollution was quite serious, and PM mass concentration was higher during the heating season than the non-heating season. PM was the highest in the chemical factory and lowest in the development zone. The mass concentrations of PM10 and PM2.5 were linearly related, and the mass concentration ratio of PM2.5/PM10 was up to 0.59 in urban areas. PM pollution in Jinan was related to local meteorological factors: PM2.5 mass concentration and humidity were positively correlated, and PM2.5 mass concentration was negatively correlated with both click on the temperature and wind speed, although wind speed varied more. 相似文献