Chemical cycling and deposition of atmospheric mercury: Global constraints from observations

Selin, Noelle E.; Jacob, Daniel J.; Park, Rokjin J.; Yantosca, Robert M.; Strode, Sarah A.; Jaeglé, Lyatt; Jaffe, Daniel A.

doi:10.1029/2006jd007450

Cited by 407 publications

(516 citation statements)

References 75 publications

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“…This is similar to current estimates of the lifetime of Hg 0 against oxidation by ozone [e.g., Selin et al, 2006] and could account for a large part of the Hg 0 loss within the 0.5-2 yr observational constraint on the atmospheric lifetime of total mercury. We find that $85% of the Hg(II) formed is HgBrOH.…”

supporting

confidence: 74%

“…This would be an important, and possibly dominant, global pathway for oxidation and deposition of atmospheric mercury. It could reconcile the atmospheric evidence that Hg 0 oxidation is photochemically mediated [Bergan and Rodhe, 2001;Selin et al, 2006] with the evidence against a major role for oxidation by OH [Calvert and Lindberg, 2005]. The mechanism appears qualitatively consistent with mercury observations -the seasonal cycle of Hg 0 ; airborne particulate mercury measurements; and gaseous Hg(II) in Antarctic summer -but global CTMs are necessary for more stringent quantitative tests.…”

supporting

confidence: 56%

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Global lifetime of elemental mercury against oxidation by atomic bromine in the free troposphere

Holmes

Jacob

Yang

2006

Geophysical Research Letters

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218

237

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[1] We calculate the global mean atmospheric lifetime of elemental mercury (Hg 0 ) against oxidation by atomic bromine (Br) in the troposphere by combining recent kinetic data for the Hg-Br system with modeled global concentrations of tropospheric Br. We obtain a lifetime of 0.5-1.7 years based on the range of kinetic data, implying that oxidation of Hg 0 by Br is a major, and possibly dominant, global sink for Hg 0 . Most of the oxidation takes place in the middle and upper troposphere, where Br concentrations are high and where cold temperatures suppress thermal decomposition of the HgBr intermediate. This oxidation mechanism is consistent with mercury observations, including in particular high gaseous Hg(II) concentrations in Antarctic summer. Better freetropospheric measurements of bromine radicals and further kinetic study of the Hg-Br system are essential to more accurately assess the global importance of Br as an oxidant of atmospheric Hg 0 . Citation:

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supporting

confidence: 74%

supporting

confidence: 56%

Global lifetime of elemental mercury against oxidation by atomic bromine in the free troposphere

Holmes

Jacob

Yang

2006

Geophysical Research Letters

Self Cite

218

237

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“…Previous studies have assumed O 3 and OH to be the major Hg 0 oxidants in the atmosphere [51][52][53][54][55][56]. Despite theoretical doubts concerning the thermal stability of gaseous HgOH and HgO products, many modeling results using O 3 /OH as the main atmospheric Hg oxidants showed good agreement with the observed Hg 0 concentration and wet deposition flux.…”

Section: Dominant Gaseous Oxidant For Hg 0 : O 3 /Oh Br or Others?mentioning

confidence: 68%

Recent Advances in Atmospheric Chemistry of Mercury

Ariya

2018

Atmosphere

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Mercury is one of the most toxic metals and has global importance due to the biomagnification and bioaccumulation of organomercury via the aquatic food web. The physical and chemical transformations of various mercury species in the atmosphere strongly influence their composition, phase, transport characteristics and deposition rate to the ground. Modeling efforts to evaluate the mercury cycling in the environment require an accurate understanding of atmospheric mercury chemistry. We focus this article on recent studies (since 2015) on improving our understanding of the atmospheric chemistry of mercury. We discuss recent advances in (i) determining the dominant atmospheric oxidant of elemental mercury (Hg 0 ); (ii) understanding the oxidation reactions of Hg 0 by halogen atoms and by nitrate radical (NO 3 ); (iii) the aqueous reduction of oxidized mercury compounds (Hg II ); and (iv) the heterogeneous reactions of Hg on atmospherically-relevant surfaces. The need for future research to improve understanding of the fate and transformation of mercury in the atmosphere is also discussed.

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“…Natural emissions, including the emission from geologic sources and the reemission of previously deposited Hg, make up approximately two thirds of global Hg emission [Schroeder and Munthe, 1998]. Human activities emit 1960 Mg of Hg into the atmosphere per year with Asia contributing >50% of the release (777 Mg yr À1 from East and Southeast Asia) [Pirrone et al, 2010;Selin et al, 2007;United Nations Environment Programme, 2013]. East China (including Shanghai, Anhui, Jiangsu, Zhejiang, Fujian, Jiangxi, and Shandong Provinces) is an important source region of atmospheric Hg in China, constituting approximately 20% of the total emissions [Wu et al, 2006].…”

Section: Introductionmentioning

confidence: 99%

Characteristics and potential sources of atmospheric mercury at a subtropical near‐coastal site in East China

et al. 2015

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To evaluate the impact of regional mercury (Hg) emissions and understand possible source regions of atmospheric Hg in Eastern China, 2 year observation for speciated atmospheric Hg was conducted at the Dameishan Atmospheric Observatory, a mountain site near the east coast of China. The observed concentration of total gaseous Hg (TGM) was 3.3 ± 1.4 ng m À3 . During the sampling period, gaseous oxidized Hg and particulate bound Hg were 6.7 ± 4.3 pg m À3 and 180 ± 110 pg m À3 in winter and 5.9 ± 3.4 pg m À3 and 130 ± 100 pg m À3 in spring, respectively. The relatively high mean concentration of TGM was mainly caused by regional anthropogenic emissions and occasional long-range transport from domestic source regions. Seasonal variation in the TGM concentration was observed with lower values in the wet monsoon season (from May to September) and higher values in the dry monsoon season (from October to April). Backward trajectories and potential source contribution function analysis suggested that anthropogenic Hg emission from coal combustion in the Yangtze River Delta region was the most likely cause for the elevated TGM concentrations. Relatively clean air originating from the East China Sea was the most possible cause for the observed low TGM concentrations. Positive correlation between TGM concentration and air quality index suggests that emissions that influenced regional air quality contributed to the elevated TGM concentrations.

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Chemical cycling and deposition of atmospheric mercury: Global constraints from observations

Cited by 407 publications

References 75 publications

Global lifetime of elemental mercury against oxidation by atomic bromine in the free troposphere

Global lifetime of elemental mercury against oxidation by atomic bromine in the free troposphere

Recent Advances in Atmospheric Chemistry of Mercury

Characteristics and potential sources of atmospheric mercury at a subtropical near‐coastal site in East China

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