研究报告

  • 马召辉,梁云平,张健,张大伟,石爱军,胡京南,林安国,冯亚君,胡月琪,刘保献.北京市典型排放源PM2.5成分谱研究[J].环境科学学报,2015,35(12):4043-4052

  • 北京市典型排放源PM2.5成分谱研究
  • PM2.5 profiles of typical sources in Beijing
  • 基金项目:北京市科技计划项目(No.Z121100000312035)
  • 作者
  • 单位
  • 马召辉
  • 大气颗粒物监测技术北京市重点实验室, 北京市环境保护监测中心, 北京 100048
  • 梁云平
  • 大气颗粒物监测技术北京市重点实验室, 北京市环境保护监测中心, 北京 100048
  • 张健
  • 大气颗粒物监测技术北京市重点实验室, 北京市环境保护监测中心, 北京 100048
  • 张大伟
  • 大气颗粒物监测技术北京市重点实验室, 北京市环境保护监测中心, 北京 100048
  • 石爱军
  • 大气颗粒物监测技术北京市重点实验室, 北京市环境保护监测中心, 北京 100048
  • 胡京南
  • 中国环境科学研究院, 北京 100012
  • 林安国
  • 大气颗粒物监测技术北京市重点实验室, 北京市环境保护监测中心, 北京 100048
  • 冯亚君
  • 大气颗粒物监测技术北京市重点实验室, 北京市环境保护监测中心, 北京 100048
  • 胡月琪
  • 大气颗粒物监测技术北京市重点实验室, 北京市环境保护监测中心, 北京 100048
  • 刘保献
  • 大气颗粒物监测技术北京市重点实验室, 北京市环境保护监测中心, 北京 100048
  • 摘要:为了建立和完善北京市PM2.5本地化源谱,对北京市11类排放源PM2.5进行采集,并测定其26种组分,分析了不同排放源源谱的组分特征.结果表明,在有组织排放源中,燃煤电厂PM2.5中OC和Si含量很高,占PM2.5的质量分数分别为8.56%和6.19%(平均值),而供热/工业锅炉排放PM2.5中则是SO42-(占48.38%)和OC(11.0%)比例最高,水泥窑炉PM2.5中OC(7.12%)、Ca(4.81)和Si(4.41%)占有较大比例;垃圾焚烧排放的PM2.5中Si、Ca、K和SO42-均较高,分别占8.15%、9.36%、7.17%和6.79%,且Cl-含量(2.5%)高于其他所有源,生物质燃烧源PM2.5中OC(21.7%)、Si(6.75%)、Ca(6.15%)较为丰富,餐饮源PM2.5中OC(19.44%)、SO42-(5.76%)和K(3.11%)含量均较高;无组织开放源中,道路扬尘和土壤风沙PM2.5化学组分含量变化较为一致,均是Si(分别为16.8%和9.3%)和OC(分别为8.89%和6.61%)最高,建筑水泥尘PM2.5中Ca(17.46%)含量高于其他源;流动排放源PM2.5中OC、EC比例最高,其中,重型柴油车的OC(29.79%)与EC(26.5%)排放比例相当,而轻型汽油车OC排放占有绝对优势(占75%).本文通过对比国内外部分排放源PM2.5成分谱的差异,指出不同区域相同源类排放的PM2.5化学组分差异较大,在应用受体模型中的化学质量平衡模型(CMB)判断受体颗粒物来源时,应基于本地的排放源成分谱,以避免较大的误差.
  • Abstract:For the purpose of establishing and improving the local PM2.5 source profiles of Beijing, PM2.5 samples were collected from 11 typical emission sources. 26 different chemical constituents were characterized to identify source profiles. The results revealed that in stationary pollution sources, OC and Si were the highest constituents in coal-fired power plants, with the mean mass percentage of 8.56% and 6.19%, respectively. Dominant species were SO42-(48.38%) and OC(11.0%) in heating/industrial boiler emissions, OC(7.12%), Ca(4.81%) and Si(4.41%) in cement kilns, SO42-(8.15%), Ca(9.36%), K(7.17%), Si(6.79%) and Cl-(2.5%) in waste incineration, OC(21.7%), Si(6.75%) and Ca(6.15%) in biomass burning, and OC(19.44%), SO42-(5.76%) and K(3.11%) in catering services sources. In open sources, PM2.5 chemical composition in uncontrolled road dust and sand soil were relatively consistent, with Si(16.8% and 9.3%) and OC(8.89% and 6.61%) the most abundant constituents. Ca(17.46%)concentration in the construction of cement dust was higher than other sources. OC and EC had the highest percentages in mobile emission sources. Their contributions were similar for heavy diesel vehicles, but OC(75%)emissions were much higher for light-duty gasoline vehicles. PM2.5 source profiles reported in China and overseas showed significant differences. Therefore, local source profiles should be preferentially utilized when applying chemical mass balance(CMB) for source apportionment of PM2.5.

  • 摘要点击次数: 1919 全文下载次数: 4036