Abstract
Abstract. The individual and combined effects of global climate change and emissions changes from 2000 to 2050 on atmospheric mercury levels in the United States are investigated by using the global climate-chemistry model, CAM-Chem, coupled with a mercury chemistry-physics mechanism (CAM-Chem/Hg). Three future pathways from the Intergovernmental Panel on Climate Change (IPCC) Special Report on Emissions Scenarios (SRES) are considered, with the A1FI, A1B and B1 scenarios representing the upper, middle and lower bounds of potential climate warming, respectively. The anthropogenic and biomass burning emissions of mercury are projected from the energy use assumptions in the IPCC SRES report. Natural emissions from both land and ocean sources are projected by using dynamic schemes. TGM concentration increases are greater in the low latitudes than they are in the high latitudes, indicative of a larger meridional gradient than in the present day. In the A1FI scenario, TGM concentrations in 2050 are projected to increase by 2.1–4.0 ng m−3 for the eastern US and 1.4–3.0 ng m−3 for the western US. This spatial difference corresponds to potential increases in wet deposition of 10–14 μg m−2 for the eastern US and 2–4 μg m−2 for the western US. The increase in Hg(II) emissions tends to enhance wet deposition and hence increase the risk of higher mercury entering the hydrological cycle and ecosystem. In the B1 scenario, mercury concentrations in 2050 are similar to present level concentrations; this finding indicates that the domestic reduction in mercury emissions is essentially counteracted by the effects of climate warming and emissions increases in other regions. The sensitivity analyses show that changes in anthropogenic emissions contribute 32–53% of projected changes in mercury air concentration, while the independent contribution by climate change and its induced natural emissions change accounts for 47–68%.
Highlights
The toxic effects of mercury (Hg) are a serious concern to public health
Based on its toxicity and present pollution levels, the control of mercury emissions is an international priority (UNEP, 2008), and modeling future changes in pollutants is a useful method to support the formulation of pollution control strategies (Lin et al, 2008; Lei et al, 2012)
Lei et al.: Projections of atmospheric mercury levels and their effect on air quality. Changes in both climate and mercury emissions will determine the atmospheric concentrations of mercury compounds in the future (UNEP, 2013); changes in climate alone influence the concentration and composition of atmospheric mercury
Summary
The toxic effects of mercury (Hg) are a serious concern to public health. Much scientific effort has been expended to monitor releases of mercury compounds and assess their effects on air quality (USEPA, 2006; Cohen et al, 2007, 2011; NADP, 2008; UNEP, 2008, 2013). Many modeling studies have investigated the effects of past and present mercury pollution on air quality (Bullock and Brehme, 2002; Cohen et al, 2004; Selin et al, 2008; UNEP, 2008, 2013; Lei et al, 2013b), potential changes in future levels of atmospheric mercury compounds and their uncertainties need further examination. Lei et al.: Projections of atmospheric mercury levels and their effect on air quality Changes in both climate and mercury emissions will determine the atmospheric concentrations of mercury compounds in the future (UNEP, 2013); changes in climate alone influence the concentration and composition of atmospheric mercury. Seasonal variations and spatial differences are significant These characteristics of natural emissions reduce the effectiveness of the simple scaling method for future projections, which may not correctly present the variations of these characteristics in response to climate change.
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