Abstract
Abstract. Based on an ensemble of 17 typhoons that made landfall between 2014 and 2018, we investigate the positive and negative influences of typhoons on tropospheric ozone over southern China. With respect to the proximity of typhoon centres and the typhoon developmental stages, we find that surface ozone is enhanced when typhoons are 400–1500 km away during the initial stages of development (e.g. from 1 d before to 1 d after typhoon genesis). The positive ozone anomalies reach 10–20 ppbv above the background ozone level on average. The maximum enhancement of surface ozone appears at a radial distance of 1100–1300 km from the typhoon centre during these initial stages. As the typhoons approach southern China, the influences of these systems switch to reducing ozone and, hence, lead to negative ozone anomalies of 6–9 ppbv. Exploring the linkages between ozone variations and typhoon-induced meteorological evolution, we find that increasing temperature and weak winds in the atmospheric boundary layer (ABL) and dominating downward motions promote ozone production and accumulation over the outskirts of typhoons during typhoon initial stages, whereas deteriorating weather, accompanied by dropping temperature, wind gales and convective activity, reduces the production and accumulation of surface ozone when typhoons are making landfall. We further examine the impacts of typhoons on tropospheric ozone profiles vertically, especially the influences of typhoon-induced stratospheric intrusions on lower troposphere and surface ozone. Based on temporally dense ozone profile observations, we find two high-ozone regions, located in the ABL and the middle to upper troposphere respectively, during different typhoon stages. On average, the high-ozone region in the ABL has a maximum ozone enhancement of 10–12 ppbv at 1–1.5 km altitude during the initial typhoon stages. In the high-ozone region in the middle to upper troposphere, ozone enhancement persists over a longer period with a maximum ozone enhancement of ∼ 10 ppbv at 7–8 km altitude shortly after typhoon genesis; this value increases to ∼ 30 ppbv near 12 km altitude when typhoons reach their maximum intensity. When typhoons make landfall, negative ozone anomalies appear and extend upward with a maximum ozone reduction of 14–18 ppbv at 5 km altitude and 20–25 ppbv at 11 km altitude. Although the overall tropospheric ozone is usually reduced during typhoon landfall, we find that five of eight typhoon samples induced ozone-rich air with a stratospheric origin above 4 km altitude; moreover, in three typhoon cases, the ozone-rich air intrusions can sink to the ABL. This suggests that the typhoon-induced stratospheric intrusions play an important role in surface ozone enhancement.
Highlights
It has been noted that high-ozone (O3) episodes are frequently associated with tropical cyclones (TCs) in the warm seasons over southern China (Huang et al, 2005; Lam et al, 2005; Jiang et al, 2008; Shu et al, 2016; Chow et al, 2018; Gao et al, 2020)
The overall tropospheric ozone is usually reduced during typhoon landfall, we find that five of eight typhoon samples induced ozone-rich air with a stratospheric origin above 4 km altitude; in three typhoon cases, the ozone-rich air intrusions can sink to the atmospheric boundary layer (ABL)
When TCs approach a region, fine, hot weather is associated with strong solar radiation and high temperatures, and overwhelming downward air motions are conducive to low wind speed and a stable atmospheric boundary layer (ABL), all of which are responsible for highozone episodes in the developed and highly populated Pearl River Delta (PRD) and Yangtze River Delta (YRD) regions (e.g. Shu et al, 2016; Zhan et al, 2020)
Summary
It has been noted that high-ozone (O3) episodes are frequently associated with tropical cyclones (TCs) in the warm seasons over southern China (Huang et al, 2005; Lam et al, 2005; Jiang et al, 2008; Shu et al, 2016; Chow et al, 2018; Gao et al, 2020). TCs have been regarded as one of the main synoptic patterns influencing surface ozone concentrations, a comprehensive understanding of ozone variations in space and time attributable to typhoons making landfall is lacking, as previous studies have generally been limited to individual cases or regional domains, and have been mostly focused solely on ozone enhancement. A full insight into the evolutionary influences of typhoons making landfall, i.e. both ozone enhancement and reduction effects, would further our understanding of the contribution of typhoons to surface ozone variations and tropospheric ozone. 4 shows the vertical variations in ozone concentrations during the evolutionary processes of typhoons making landfall based on temporally dense ozone profile observations, and the impacts of typhoon-induced STE on the vertical ozone distributions is presented; Sect. The remainder of this paper is structured as follows: Sect. 2 describes the study domain and period, the ozone observations, the meteorological data, and the analysis methods; Sect. 3 presents the statistical distributions of surface ozone concentrations with reference to typhoon developmental features; Sect. 4 shows the vertical variations in ozone concentrations during the evolutionary processes of typhoons making landfall based on temporally dense ozone profile observations, and the impacts of typhoon-induced STE on the vertical ozone distributions is presented; Sect. 5 offers the conclusions, discussions and suggestions for future work
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