Zhao Bin, Jiang Jonathan H, Diner David J, Su Hui, Gu Yu, Liou Kuo-Nan, Jiang Zhe, Huang Lei, Takano Yoshi, Fan Xuehua, Omar Ali H
Joint Institute for Regional Earth System Science and Engineering and Department of Atmospheric and Oceanic Sciences, University of California, Los Angeles, California, USA.
Jet propulsion Laboratory, California Institute of Technology, Pasadena, California, USA.
Atmos Chem Phys. 2018;18(15):11247-11260. doi: 10.5194/acp-18-11247-2018. Epub 2018 Aug 13.
The climatic and health effects of aerosols are strongly dependent on the intra-annual variations in their loading and properties. While the seasonal variations of regional aerosol optical depth (AOD) have been extensively studied, understanding the temporal variations in aerosol vertical distribution and particle types is also important for an accurate estimate of aerosol climatic effects. In this paper, we combine the observations from four satellite-borne sensors and several ground-based networks to investigate the seasonal variations of aerosol column loading, vertical distribution, and particle types over three populous regions: the Eastern United States (EUS), Western Europe (WEU), and Eastern and Central China (ECC). In all three regions, column AOD, as well as AOD at heights above 800 m, peaks in summer/spring, probably due to accelerated formation of secondary aerosols and hygroscopic growth. In contrast, AOD below 800m peaks in winter over WEU and ECC regions because more aerosols are confined to lower heights due to the weaker vertical mixing. In the EUS region, AOD below 800m shows two maximums, one in summer and the other in winter. The temporal trends in low-level AOD are consistent with those in surface fine particle (PM) concentrations. AOD due to fine particles (< 0.7 μm diameter) is much larger in spring/summer than in winter over all three regions. However, the coarse mode AOD (> 1.4 μm diameter), generally shows small variability, except that a peak occurs in spring in the ECC region due to the prevalence of airborne dust during this season. When aerosols are classified according to sources, the dominant type is associated with anthropogenic air pollution, which has a similar seasonal pattern as total AOD. Dust and sea-spray aerosols in the WEU region peak in summer and winter, respectively, but do not show an obvious seasonal pattern in the EUS region. Smoke aerosols, as well as absorbing aerosols, present an obvious unimodal distribution with a maximum occurring in summer over the EUS and WEU regions, whereas they follow a bimodal distribution with peaks in August and March (due to crop residue burning) over the ECC region.
气溶胶的气候和健康影响在很大程度上取决于其负荷和特性的年内变化。虽然区域气溶胶光学厚度(AOD)的季节变化已得到广泛研究,但了解气溶胶垂直分布和颗粒类型的时间变化对于准确估算气溶胶气候效应也很重要。在本文中,我们结合了四个卫星搭载传感器和几个地面网络的观测数据,以研究美国东部(EUS)、西欧(WEU)和中国东部及中部(ECC)这三个人口密集地区气溶胶柱负荷、垂直分布和颗粒类型的季节变化。在所有这三个地区,柱AOD以及800米以上高度的AOD在夏季/春季达到峰值,这可能是由于二次气溶胶的加速形成和吸湿增长。相比之下,在WEU和ECC地区,800米以下的AOD在冬季达到峰值,因为垂直混合较弱,更多气溶胶被限制在较低高度。在美国东部地区,800米以下的AOD出现两个最大值,一个在夏季,另一个在冬季。低空AOD的时间趋势与地表细颗粒物(PM)浓度的趋势一致。在所有这三个地区,春季/夏季由细颗粒(直径<0.7μm)导致的AOD比冬季大得多。然而,粗模式AOD(直径>1.4μm)通常变化较小,不过在ECC地区春季出现一个峰值,这是由于该季节空气中沙尘盛行。当根据来源对气溶胶进行分类时,主要类型与人为空气污染相关,其季节模式与总AOD相似。WEU地区的沙尘和气溶胶分别在夏季和冬季达到峰值,但在美国东部地区没有明显的季节模式。烟雾气溶胶以及吸收性气溶胶呈现明显的单峰分布,在美国东部和西欧地区夏季出现最大值,而在中国东部地区它们呈现双峰分布,在8月和3月(由于作物秸秆燃烧)出现峰值。
