Mobilization and Transformation of Mercury Across a Dammed Boreal River Are Linked to Carbon Processing and Hydrology

Mobilization and Transformation of Mercury Across a Dammed Boreal River Are Linked to Carbon Processing and Hydrology

Reservoirs are known to accelerate the mobilization and cycling of mercury and carbon as a result of flooding of terrestrial organic matter, which can lead to environmental concerns at local and broader spatial scales. We explored the covariation of mercury (Hg) and carbon (C) functional pools in na...

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Veröffentlicht in:Water resources research 2020-10, Vol.56 (10), p.n/a
Hauptverfasser: De Bonville, Jeremy, Amyot, Marc, Giorgio, Paul, Tremblay, Alain, Bilodeau, François, Ponton, Dominic E., Lapierre, Jean‐François
Format: Artikel
Sprache:eng
Schlagworte:
Anoxia
Carbon
Carbon dioxide
Carbon dioxide concentration
Dichotomies
Dissolved organic carbon
Environmental conditions
flood
Flooding
Fluvial sediments
Hydrology
Manganese
Mercury
Mercury (metal)
Metabolism
methylmercury
Organic carbon
Organic matter
PARAFAC
Pools
Reservoirs
River sediments
Rivers
Sediments
Surface water
Watersheds
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Zusammenfassung:Reservoirs are known to accelerate the mobilization and cycling of mercury and carbon as a result of flooding of terrestrial organic matter, which can lead to environmental concerns at local and broader spatial scales. We explored the covariation of mercury (Hg) and carbon (C) functional pools in natural and recently dammed portions of the aquatic network of the Romaine River watershed in Northern Quebec, Canada, to understand how the fate of these elements varies across systems with contrasting hydrology and environmental conditions. We found that total Hg (THg) concentrations in surface waters were relatively constant along the network, whereas both the concentrations and proportions of MeHg tended to increase in reservoirs compared to surrounding nonflooded systems, and along the cascade of reservoirs. Whereas THg was related to total and terrestrial pools of dissolved organic carbon (DOC), MeHg was weakly related to DOC but strongly linked to surface concentrations of CO2, as well as to concentrations of iron and manganese. The latter are proxies of cumulative organic matter processing within the network, presumably in anoxic portions of shallow bays, deep reservoir waters, and river sediments, as well as in prior seasons (e.g., under ice). Our results suggest that these deep boreal reservoirs acted more as transformation sites for Hg that was already present than as mobilizers of new Hg, and that under ice metabolism plays a role in MeHg production in these systems as we found strong dichotomies in MeHg patterns between spring and summer. Key Points We observed an increase in methylmercury concentrations but stable total mercury concentrations along a hydroelectric reservoirs sequence Methylmercury was linked to carbon dioxide, peaking in spring, consistent with accumulation and production in the winter under ice cover Methylmercury patterns were linked to signs of organic matter processing occurring months prior, and kilometers upstream
ISSN:0043-1397
1944-7973
DOI:10.1029/2020WR027951