Evolution of particle number size distribution in an urban atmosphere during episodes of heavy pollution and new particle formation 被引量：8

Evolution of particle number size distribution in an urban atmosphere during episodes of heavy pollution and new particle formation

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摘要 This study discusses the evolution of particle number size distribution during episodes of heavy pollution and new particle formation in the urban atmosphere of Beijing to quantify the effects of dynamic processes (coagulation and condensation) on the particle number size distribution.During a heavy-pollution event,an extremely low number concentration of 3-10 nm particles (on average 46 cm-3) was observed.This is because nucleation-mode particles were easily removed by strong coagulational scavenging of larger particles under this condition.In addition,a large condensation sink (on average 0.13 s-1) restrained nucleation,which is one of the major sources of nucleation-mode particles.Conversely,during a new-particle formation event,the small condensation sink (0.01 s-1) of precursor facilitated nucleation.At the same time,preexisting particles had little ability to scavenge newly formed particles (around 1 nm) and allowed them to grow to a detectable size (larger than 3 nm currently).We suggest that the effects of dynamic processes (coagulation and condensation) on particle size distribution should be stressed under some extreme conditions of the relatively polluted urban atmosphere in addition to traffic and meteorological factors. This study discusses the evolution of particle number size distribution during episodes of heavy pollution and new particle formation in the urban atmosphere of Beijing to quantify the effects of dynamic processes （coagulation and condensation） on the particle number size distribution. During a heavy-pollution event, an extremely low number concentration of 3-10 nm particles （on average 46 cm-3） was observed. This is because nucleation-mode particles were easily removed by strong coagulational scavenging of larger particles under this condition. In addition, a large condensation sink （on average 0.13 s-1） restrained nucleation, which is one of the major sources of nucleation-mode particles. Conversely, during a new-particle formation event, the small condensation sink （0.01 s-1） of precursor facilitated nucleation. At the same time, preexisting particles had little ability to scavenge newly formed particles （around 1 nm） and allowed them to grow to a detectable size （larger than 3 nm currently）. We suggest that the effects of dynamic processes （coagulation and condensation） on particle size distribution should be stressed under some extreme conditions of the relatively polluted urban atmosphere in addition to traffic and meteorological factors.

作者 WU ZhiJun, HU Min YUE DingLi Birgit WEHNER Alfred WIEDENSOHLER

机构地区 State Key Joint Laboratory of Environmental Simulation and Pollution Control Leibniz-lnstitutefor Tropospheric Research

出处《Science China Earth Sciences》 SCIE EI CAS 2011年第11期1772-1778,共7页 中国科学（地球科学英文版）

基金 supported by National Natural Science Foundation of China (Grant No. 20977001,21025728)

关键词 particle number size distribution new particle formation coagulation and condensation sinks 城市大气污染粒子数分布演变气氛粒子数浓度大小分布分布动态粒度分布

分类号 X51 [环境科学与工程—环境工程] TN248.2 [电子电信—物理电子学]

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