[1] T Zhu, J Shang, D F Zhao. The roles of heterogeneous chemical processes in the formation of an air pollution complex and gray haze. Scientia Sinica: Chimica, 40, 1731-1740(2010).
[2] J Q Zhang, D T Luo, H Wang et al. Characteristics and source of carbonaceous species in particulate matter during winter in Langfang City development zones. Research of Environmental Sciences, 32, 1818-1825(2019).
[3] T T Liao, S Wang, J Ai et al. Heavy pollution episodes, transport pathways and potential sources of PM2.5 during the winter of 2013 in Chengdu. Science of the Total Environment, 584/585, 1056-1065(2017).
[4] H M Chen, B L Zhuang, J Liu et al. Regional climate responses in east Asia to the black carbon aerosol direct effects from India and China in summer. Journal of Climate, 33, 9783-9800(2020).
[5] K Cao, W T Zhang, S B Liu et al. Pareto law-based regional inequality analysis of PM2.5 air pollution and economic development in China. Journal of Environmental Management, 252, 1-9(2019).
[6] D Wu, J T Mao, X J Deng et al. Black carbon aerosols and their radiative properties in the Pearl River Delta region. Science China (Series D), 39, 1542-1553(2009).
[7] M J Mao, R G Du, J Wu. Influences of the G20 emission reduction on characteristics of water-soluble ions in PM in Hangzhou. China Environmental Science, 39, 2283-2290(2019).
[8] Y W Qu, T J Wang, H Wu et al. Vertical structure and interaction of ozone and fine particulate matter in spring at Nanjing, China: The role of aerosol's radiation feedback. Atmospheric Environment, 222, 117162(2020).
[9] P F Liu, C S Zhao, T Gödel et al. Hygroscopic properties of aerosol particles at high relative humidity and their diurnal variations in the North China Plain. Atmospheric Chemistry and Physics, 11, 3479-3494(2011).
[10] C Liu, T J Wang, D Rosenfeld et al. Anthropogenic effects on cloud condensation nuclei distribution and rain initiation in east Asia. Geophysical Research Letters, 47, e2019GL086184(2020).
[11] G Yamamoto, M Tanaka. Increase of global albedo due to air pollution. Journal of the Atmospheric Sciences, 29, 1405-1412(1972).
[12] M J Mao, H T Liu, R G Du. Characteristics and control factors of ozone pollution at different time scales in Hangzhou city. Research of Environmental Sciences, 32, 1844-1851(2019).
[13] G A Da, X A Min, C A Xing et al. Systematic classification of circulation patterns and integrated analysis of their effects on different ozone pollution levels in the Yangtze River Delta Region, China. Atmospheric Environment, 242, 117760(2020).
[14] H Han, J Liu, L Shu et al. Local and synoptic meteorological influences on daily variability in summertime surface ozone in Eastern China. Atmospheric Chemistry and Physics, 20, 203-222(2020).
[15] C C Zhan, M Xie, C W Huang et al. Ozone affected by a succession of four landfall typhoons in the Yangtze River Delta, China: Major processes and health impacts. Atmospheric Chemistry and Physics, 20, 13781-13799(2020).
[16] K H Lee, Y J Kim, J K Min. Characteristics of aerosol observed during two severe haze events over Korea in June and October 2004. Atmospheric Environment, 40, 5146-5155(2006).
[17] S Q Wang, W B Li, X J Deng et al. Characteristics of air pollutant transport channels in Guangzhou region. China Environmental Science, 35, 2883-2890(2015).
[18] D T Shindell, M Chin, F Dentener et al. A multi-model assessment of pollution transport to the Arctic. Atmospheric Chemistry and Physics, 8, 5353-5372(2008).
[19] D Bella, J Culpepper, J Khaimova et al. Characterization of pollution transport into Texas using OMI and TES satellite, GIS and in situ data, and HYSPLIT back trajectory analyses: Implications for TCEQ State Implementation Plans. Air Quality, Atmosphere & Health, 9, 569-588(2016).
[20] Z G Zhang, Q X Gao, X Q Han et al. The study of pollutant transport between the cities in North China. Research of Environmental Sciences, 17, 14-20(2004).
[21] Y Wang, F H Chai, H F Liu et al. Analysis on the characteristics of horizontal transport of the atmospheric pollutant over the Yangtze delta. Research of Environmental Sciences, 21, 22-29(2008).
[22] A Comerón, C Muñoz-Porcar, F Rocadenbosch et al. Current research in lidar technology used for the remote sensing of atmospheric aerosols. Sensors, 17, 1450(2017).
[23] S Pal, T R Lee, S Phelps et al. Impact of atmospheric boundary layer depth variability and wind reversal on the diurnal variability of aerosol concentration at a valley site. Science of the Total Environment, 496, 424-434(2014).
[24] K J Voss, E J Welton, P K Quinn et al. Lidar measurements during Aerosols99. Journal of Geophysical Research: Atmospheres, 106, 20821-20831(2001).
[25] T Deng, D Wu, X J Deng et al. A vertical sounding of severe haze process in Guangzhou area. Science China Earth Sciences, 57, 2650-2656(2014).
[26] D Liu, Z F Zheng, W B Chen et al. Performance estimation of space-borne high-spectral-resolution lidar for cloud and aerosol optical properties at 532 nm. Optical Express, 27, A481-A494(2019).
[27] M Y Li, M Fan, J H Tao et al. The space-borne lidar cloud and aerosol classification algorithms. Spectroscopy and Spectral Analysis, 39, 383-391(2019).
[28] N Ma, S P Yang, J Wang et al. Joint observation of a haze episode in Beijing-Tianjin-Hebei region with space borne and ground-based lidar. Environmental Monitoring in China, 35, 147-156(2019).
[29] F G Fernald. Analysis of atmospheric lidar observations: Some comments. Applied Optics, 23, 652-653(1984).
[30] J D Klett. Stable analytical inversion solution for processing lidar returns. Applied Optics, 20, 211-220(1981).
[31] H T Liu, M J Mao. An accurate inversion method of aerosol extinction coefficient about ground-based lidar without needing calibration. Acta Physica Sinica, 68, 074205(2019).
[32] Y J Yuan, D M Ren, X Y Hu. Computing scattering phase function by recursive formula of Mie theory. Chinese Journal of Light Scattering, 17, 366-371(2005).
[33] X B Li, S X Hu, W Y Zhu et al. Characteristics of aerosol size distribution in Hefei, Yuexi, Xiamen and Beijing. Journal of Atmospheric and Environmental Optics, 6, 154-162(2011).
