Sources of riverine mercury across the Mackenzie River Basin; inferences from a combined HgC isotopes and optical properties approach

The Arctic environment harbors a complex mosaic of mercury (Hg) and carbon (C) reservoirs, some of which are rapidly destabilizing in response to climate warming. The sources of riverine Hg across the Mackenzie River basin (MRB) are uncertain, which leads to a poor understanding of potential future...

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Published in:The Science of the total environment Vol. 806; no. Pt 4; p. 150808
Main Authors: Campeau, Audrey, Eklöf, Karin, Soerensen, Anne L., Åkerblom, Staffan, Yuan, Shengliu, Hintelmann, Holger, Bieroza, Magdalena, Köhler, Stephan, Zdanowicz, Christian
Format: Journal Article
Language:English
Published: Netherlands Elsevier B.V 01-02-2022
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Summary:The Arctic environment harbors a complex mosaic of mercury (Hg) and carbon (C) reservoirs, some of which are rapidly destabilizing in response to climate warming. The sources of riverine Hg across the Mackenzie River basin (MRB) are uncertain, which leads to a poor understanding of potential future release. Measurements of dissolved and particulate mercury (DHg, PHg) and carbon (DOC, POC) concentration were performed, along with analyses of Hg stable isotope ratios (incl. ∆199Hg, δ202Hg), radiocarbon content (∆14C) and optical properties of DOC of river water. Isotopic ratios of Hg revealed a closer association to terrestrial Hg reservoirs for the particulate fraction, while the dissolved fraction was more closely associated with atmospheric deposition sources of shorter turnover time. There was a positive correlation between the ∆14C-OC and riverine Hg concentration for both particulate and dissolved fractions, indicating that waters transporting older-OC (14C-depleted) also contained higher levels of Hg. In the dissolved fraction, older DOC was also associated with higher molecular weight, aromaticity and humic content, which are likely associated with higher Hg-binding potential. Riverine PHg concentration increased with turbidity and SO4 concentration. There were large contrasts in Hg concentration and OC age and quality among the mountain and lowland sectors of the MRB, which likely reflect the spatial distribution of various terrestrial Hg and OC reservoirs, including weathering of sulfate minerals, erosion and extraction of coal deposits, thawing permafrost, forest fires, peatlands, and forests. Results revealed major differences in the sources of particulate and dissolved riverine Hg, but nonetheless a common positive association with older riverine OC. These findings reveal that a complex mixture of Hg sources, supplied across the MRB, will contribute to future trends in Hg export to the Arctic Ocean under rapid environmental changes. [Display omitted] •Sources differ between the particulate and dissolved Hg fractions.•Dissolved Hg is more strongly associated with atmospheric deposition.•Particulate Hg is consistently associated with terrestrial sources.•Riverine Hg concentration are positively correlated with Organic Carbon age.•River chemistry is strongly contrasted between the Mountain and Lowland area.
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ISSN:0048-9697
1879-1026
DOI:10.1016/j.scitotenv.2021.150808