Evolution of Aerosol Vertical Distribution During Particulate Pollution Events in Shanghai

作     者：张云伟 张群 冷春鹏 张德芹 成天涛 陶俊 张仁健 贺千山 

作者机构：Shanghai Key Laboratory of Atmospheric Particle Pollution and PreventionDepartment of Environmental Science & EngineeringFudan University Fudan-Tyndall CentreFudan University South China Institute of Environmental SciencesMinistry of Environmental Protection Key Laboratory of Regional Climate-Environment Research for Temperate East AsiaInstitute of Atmospheric PhysicsChinese Academy of Sciences Shanghai Meteorological Bureau 

出 版 物：《Journal of Meteorological Research》 (气象学报（英文版）)

年 卷 期：2015年第29卷第3期

页      面：385-399页

核心收录：

学科分类：07[理学] 0707[理学-海洋科学] 070602[理学-大气物理学与大气环境] 0706[理学-大气科学] 

基　　金：Supported by the National Science and Technology Support Programe of China(2014BAC16B01) National Natural Science Foundation of China(41475109,21190053,and 21177025) Shanghai Science and Technology Commission of Shanghai Municipality(12DJ1400100 and 12DZ2260200) Jiangsu Collaborative Innovation Center for Climate Change,Priority Fields for Ph.D.Programs of Foundation of Ministry of Education of China(0110071130003) FP7 Project(AMIS,PIRSES-GA-2011) Program for New Century Excellent Talents in University(NCET) 

主　　题：aerosol vertical distribution planetary boundary layer haze 

摘      要：A set of micro pulse lidar （MPL） systems operating at 532 nm was used for ground-based observation of aerosols in Shanghai in 2011. Three typical particulate pollution events （e.g., haze） were examined to determine the evolution of aerosol vertical distribution and the planetary boundary layer （PBL） during these pollution episodes. The aerosol vertical extinction coefficient （VEC） at any given measured altitude was prominently larger during haze periods than that before or after the associated event. Aerosols originating from various source regions exerted forcing to some extent on aerosol loading and vertical layering, leading to different aerosol vertical distribution structures. Aerosol VECs were always maximized near the surface owing to the potential influence of local pollutant emissions. Several peaks in aerosol VECs were found at altitudes above 1 km during the dust- and bioburningoinfluenced haze events. Aerosol VECs decreased with increasing altitude during the local-polluted haze event, with a single maximum in the surface atmosphere. PM2.5 increased slowly while PBL and visibility decreased gradually in the early stages of haze events; subsequently, PM2.5 accumulated and was exacerbated until serious pollution bursts occurred in the middle and later stages. The results reveal that aerosols from different sources impact aerosol vertical distributions in the atmosphere and that the relationship between PBL and pollutant loadings may play an important role in the formation of pollution.