Abstract
ABSTRACT Rainwater samples were collected between 2010 and 2013 at Lulin Atmospheric Background Station (LABS) to study the distribution and characteristics of wet mercury (Hg) deposition, and possible driving mechanisms. Sample Hg concentrations ranged from 0.8 to 35.1 ng L–1 with an overall volume-weighted mean (VWM) concentration of 9.2 ng L–1. Annual wet Hg deposition fluxes ranged between 24.4 and 48.9 µg m–2 with a mean value of 32.3 µg m–2. This mean annual wet flux was about 1.5–6.0 times the values measured at 15 sites in the U.S. and 4–16 times the values reported from mountain and high-elevation sites in China. Both rainwater Hg concentration and rainfall amount contributed to this geographical difference, but rainfall amount played a more important role. This indicated that tropical mountains in East and Southeast Asia, especially the windward maritime slopes with abundant rainfall, could be hot spots of wet Hg deposition. Wet Hg deposition flux was high in summer because of elevated rainwater Hg concentrations and high rainfall. The seasonal pattern of rainwater Hg concentrations was different from that of the East Asian air pollutant export, indicating other factors, e.g., rainfall type, were also influencing rainwater Hg concentrations. A clear difference in seasonal frequency distribution of rainfall types was observed, with rain events associated with the Pacific high pressure type (PH) occurring more frequently in summer months. PH rainfall type had the highest VWM Hg concentration (13.5 ng L–1), 2.3–6.2 ng L–1 greater than those of the other rainfall types. Because of intense surface heating under summer PH conditions, precipitation systems usually form locally due to strong convection, resulting in afternoon shower. Therefore, the elevated rainwater Hg levels in summer at LABS were likely due to the scavenging of free tropospheric gaseous oxidized Hg (GOM) by deep convection.
Highlights
Mercury (Hg) is a persistent and bioaccumulative toxicant of global concern with widespread anthropogenic emission sources (UNEP, 2013)
There was a weak but statistically significant inverse correlation between the rainwater Hg concentration and weekly rainfall (Fig. 2; R2 = 0.036, p = 0.022), indicating rainwater Hg concentrations decreases with increasing rainfall
This result is similar to previous studies that observed a significant inverse correlation between rainfall and rainwater Hg concentration (Prestbo and Gay, 2009; Seo et al, 2012; Wang et al, 2012; Hansen and Gay, 2013; Sheu and Lin, 2013)
Summary
Mercury (Hg) is a persistent and bioaccumulative toxicant of global concern with widespread anthropogenic emission sources (UNEP, 2013). These results, suggested that other factors, such as meteorological conditions, rainfall types, atmospheric chemistry, and Hg emissions and transport (Prestbo and Gay, 2009; Shah et al, 2016; Mao et al, 2017a, b; Shah and Jaeglé 2017; Sprovieri et al, 2017) could contribute to the difference in rainwater Hg concentrations between the LABS and the Chinese mountain sites.
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