Sources and Transformation Mechanisms of Atmospheric Particulate Bound Mercury Revealed by Mercury Stable Isotopes

Liu, Chen; Fu, Xuewu; Yue, Xu; Zhang, Hui; Wu, Xian; Sommar, Jonas; Zhang, Leiming; Wang, Xun; Feng, Xinbin

doi:10.1021/acs.est.1c08065

Cited by 17 publications

(28 citation statements)

References 79 publications

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“…Most physical and chemical processes lead to MDF, but odd-MIF is mainly produced by photochemical reactions (e.g. photoreduction of aqueous Hg(II), photodemethylation of methylmercury). − Even-MIF is mainly observed in atmospheric samples, and its mechanism may be attributed to atmospheric redox processes. − Previous studies have reported Hg isotopes of PBM in different regions (e.g., urban, rural, and coastal areas) ,− and seasonal even diurnal variation of odd-MIF ,, and indicate that the isotopic compositions of PBM emitted from primary sources would be modified during atmospheric transformation or transportation. However, the mechanism that drives Hg isotope variations of PBM is still poorly understood, especially during the transformations of PBM in severe haze events.…”

Section: Introductionmentioning

confidence: 99%

Stable Isotopes Reveal Photoreduction of Particle-Bound Mercury Driven by Water-Soluble Organic Carbon during Severe Haze

Zhang

Zheng

Sun

et al. 2022

Environ. Sci. Technol.

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Haze with high loading of particles may result in significant enrichment of particle-bound Hg (PBM), potentially impacting the atmospheric Hg transformation and transport. However, the dynamics of Hg transformation and the relative environmental effect during severe haze episodes remain unclear. Here, we report Hg isotopic compositions of atmospheric particles (PM 2.5 , PM 10 , and TSP) collected during a severe haze episode in Tianjin, China, to investigate the transformation and fate of Hg during haze events. All severe haze samples display significantly higher Δ 199 Hg (up to 1.50‰) than global urban PBM, which cannot be explained by primary anthropogenic emissions. The high Δ 199 Hg is likely caused by photoreduction of PBM promoted by water-soluble organic carbon (WSOC) during the particle accumulation period, as demonstrated by the positive correlations of Δ 199 Hg with WSOC and relative humidity and confirmed by our laboratory-controlled photoreduction experiment. The results show that, on average, 21% of PBM are likely photoreduced and re-emitted back to the atmosphere as Hg(0), potentially requiring revision of atmospheric Hg budgeting and modeling. This study highlights the release of large portions of PBM back to the gas phase through photoreduction, which needs to be taken into account while evaluating the atmospheric Hg cycle and the relative ecological effects.

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Section: Introductionmentioning

confidence: 99%

Stable Isotopes Reveal Photoreduction of Particle-Bound Mercury Driven by Water-Soluble Organic Carbon during Severe Haze

Zhang

Zheng

Sun

et al. 2022

Environ. Sci. Technol.

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“…3h, i ), in which terrestrial Hg inputs are limited, provide a promising reservoir for tracking atmospheric fluxes of Hg 23 . For the pelagic Gujo-Hachiman section, the negative or near-zero Δ 199 Hg values associated with Hg concentration peaks near the LPME, document elevated fluxes of isotopically light Hg because Δ 199 Hg becomes more positive during atmospheric transport 24 . Combustion of terrestrial organic-rich sediments (e.g., coal 27 ), which can lead to elevated Hg concentrations 28 with a negative MIF in marine deposits 29 , was the likely dominant source of Hg at a global scale 14 (Fig.…”

Section: Discussionmentioning

confidence: 96%

“…1 ). These positive excursions were likely due to photoreduction of Hg(II) during long-distance transport through the atmosphere 24 . Moreover, the sharp decrease of pyrite sulfur isotope (δ 34 S) values coinciding with the extinction interval in the Bunnerong core provides evidence for increasing atmospheric sulfate concentrations, which have been previously linked to aerosol production by the STLIP 32 .…”

Section: Discussionmentioning

confidence: 98%

“…Although Δ 199 Hg has been widely used to track Hg sources during the Permian–Triassic transition 14 , 16 , 18 , interpretation of Hg isotopes in sediments can be complicated. Several factors influence Δ 199 Hg: (1) the proportions of Hg sourced from the mantle (near-zero MIF 22 ) versus organic-rich sediments by sills and/or combustion of vegetation and soil by wildfires (negative MIF 23 ); (2) the magnitude of Hg fractionation during atmospheric transport, which ranges from 0.1 to 0.8‰ in the modern atmosphere 24 ; and (3) mixing of multiple Hg sources, including terrestrial runoff, atmospheric removal, and seawater loading, in terrestrial and nearshore facies 16 , 17 , 25 , 26 . In Permian–Triassic successions, Δ 199 Hg shows large variations in different settings, with near-zero values in deep-shelf to slope settings but negative excursions in continental, shallow-shelf, deep-basinal, and pelagic settings (Fig.…”

Section: Discussionmentioning

confidence: 99%

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Mercury evidence from southern Pangea terrestrial sections for end-Permian global volcanic effects

Shen

Chen

et al. 2023

Nat Commun

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The latest Permian mass extinction (LPME) was triggered by magmatism of the Siberian Traps Large Igneous Province (STLIP), which left an extensive record of sedimentary Hg anomalies at Northern Hemisphere and tropical sites. Here, we present Hg records from terrestrial sites in southern Pangea, nearly antipodal to contemporaneous STLIP activity, providing insights into the global distribution of volcanogenic Hg during this event and its environmental processing. These profiles (two from Karoo Basin, South Africa; two from Sydney Basin, Australia) exhibit significant Hg enrichments within the uppermost Permian extinction interval as well as positive Δ199Hg excursions (to ~0.3‰), providing evidence of long-distance atmospheric transfer of volcanogenic Hg. These results demonstrate the far-reaching effects of the Siberian Traps as well as refine stratigraphic placement of the LPME interval in the Karoo Basin at a temporal resolution of ~105 years based on global isochronism of volcanogenic Hg anomalies.

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“…Before PBM samples were collected onto the filters, multiple atmospheric processes [e.g., oxidation of GEM to GOM followed by adsorption onto particulates, direct uptake of GEM, and photoreduction of Hg(II) in particulates] might occur and alter the isotope compositions of initial PBM sourced from anthropogenic emissions. 67 These processes could produce significant MIF, but their net effect typically imparts the collected PBM with positive odd-MIF values and Δ 199 Hg/Δ 201 Hg slopes of ∼1.0 [diagnostic of the magnetic isotope effect (MIE)] but sometimes up to 1.6 [diagnostic of the nuclear volume effect (NVE)]. 67 In addition, significant correlations of Δ 200 Hg versus Δ 199 Hg and Δ 204 Hg versus Δ 200 Hg were also typically observed in atmospheric samples (Figures 3D−F and 4D−F).…”

Section: Comparison With the Global Atmospheric Hgmentioning

confidence: 99%

Atmospheric Mercury Isotope Shifts in Response to Mercury Emissions from Underground Coal Fires

Sun

Cao

Dai

et al. 2023

Environ. Sci. Technol.

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Pollutant emissions from coal fires have caused serious concerns in major coal-producing countries. Great efforts have been devoted to suppressing them in China, notably at the notorious Wuda Coalfield in Inner Mongolia. Recent surveys revealed that while fires in this coalfield have been nearly extinguished near the surface, they persist underground. However, the impacts of Hg volatilized from underground coal fires remain unclear. Here, we measured concentrations and isotope compositions of atmospheric Hg in both gaseous and particulate phases at an urban site near the Wuda Coalfield. The atmospheric Hg displayed strong seasonality in terms of both Hg concentrations (5−7-fold higher in fall than in winter) and isotope compositions. Combining characteristic isotope compositions of potential Hg sources and air mass trajectories, we conclude that underground coal fires were still emitting large amounts of Hg into the atmosphere that have been transported to the adjacent urban area in the prevailing downwind direction. The other local anthropogenic Hg emissions were only evident in the urban atmosphere when the arriving air masses did not pass directly through the coalfield. Our study demonstrates that atmospheric Hg isotope measurement is a useful tool for detecting concealed underground coal fires.

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Sources and Transformation Mechanisms of Atmospheric Particulate Bound Mercury Revealed by Mercury Stable Isotopes

Cited by 17 publications

References 79 publications

Stable Isotopes Reveal Photoreduction of Particle-Bound Mercury Driven by Water-Soluble Organic Carbon during Severe Haze

Stable Isotopes Reveal Photoreduction of Particle-Bound Mercury Driven by Water-Soluble Organic Carbon during Severe Haze

Mercury evidence from southern Pangea terrestrial sections for end-Permian global volcanic effects

Atmospheric Mercury Isotope Shifts in Response to Mercury Emissions from Underground Coal Fires

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