AI Article Synopsis
- Mercury (Hg) is a harmful environmental toxicant, with its emissions controlled by various policies, and this study focuses on its sources in Boston, a major metropolitan area.
- Measurements between August 2017 and April 2019 show that atmospheric Hg levels in Boston are relatively low but suggest that actual anthropogenic emissions might be significantly underestimated, potentially 3-7 times higher than current inventories.
- The research also indicates that legacy emissions from the ocean and nonpoint land-based sources play a crucial role in the area's Hg concentrations, particularly during certain weather conditions, stressing the need for more comprehensive studies in other regions.
Article Abstract
Mercury (Hg) is an environmental toxicant dangerous to human health and the environment. Its anthropogenic emissions are regulated by global, regional, and local policies. Here, we investigate Hg sources in the coastal city of Boston, the third largest metropolitan area in the Northeastern United States. With a median of 1.37 ng m, atmospheric Hg concentrations measured from August 2017 to April 2019 were at the low end of the range reported in the Northern Hemisphere and in the range reported at North American rural sites. Despite relatively low ambient Hg concentrations, we estimate anthropogenic emissions to be 3-7 times higher than in current emission inventories using a measurement-model framework, suggesting an underestimation of small point and/or nonpoint emissions. We also test the hypothesis that a legacy Hg source from the ocean contributes to atmospheric Hg concentrations in the study area; legacy emissions (recycling of previously deposited Hg) account for ∼60% of Hg emitted annually worldwide (and much of this recycling takes place through the oceans). We find that elevated concentrations observed during easterly oceanic winds can be fully explained by low wind speeds and recirculating air allowing for accumulation of land-based emissions. This study suggests that the influence of nonpoint land-based emissions may be comparable in size to point sources in some regions and highlights the benefits of further top-down studies in other areas.
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| http://dx.doi.org/10.1039/d1em00253h | DOI Listing |
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