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A comprehensive sulfate and DOM framework to assess methylmercury formation and risk in subtropical wetlands

Brett A. Poulin, Michael T. Tate, Sarah E. Janssen, George R. Aiken, David P. Krabbenhoft

2025Nature Communications16 citationsDOIOpen Access PDF

Abstract

Abstract Wetlands play a vital role in contaminant cycling and uptake. Understanding how sulfate (SO 4 2‒ ) influences the conversion of inorganic mercury (Hg(II)) to toxic methylmercury (MeHg) is critical for predicting wetland responses to land use and climate change. Here, we sampled surface and pore waters across SO 4 2‒ gradients in three freshwater Everglades wetlands to assess linkages between SO 4 2‒ , MeHg, dissolved organic matter (DOM), and inorganic sulfide (S(‒II)). Increasing SO 4 2‒ concentrations increase S(‒II) and DOM concentrations and DOM aromaticity. MeHg concentration show a unimodal response to surface water SO 4 2‒ , which reflect high Hg(II) methylation at low-to-intermediate SO 4 2‒ concentration (2-12 mg/L) and low Hg(II) methylation at higher SO 4 2‒ concentrations ( > 12 mg/L). MeHg concentrations in surface waters correlate positively with MeHg concentrations in prey fish. The coherent biogeochemical relationships between SO 4 2‒ and MeHg concentrations and biologic uptake improve MeHg risk assessment for aquatic food webs and are globally relevant due to anthropogenic and climate-driven increases in SO 4 2‒ .

Topics & Concepts

MethylmercuryBiogeochemical cycleEnvironmental chemistryWetlandDissolved organic carbonMercury (programming language)SulfateSurface waterEnvironmental scienceAquatic ecosystemChemistryOrganic matterBioaccumulationEcologyEnvironmental engineeringBiologyComputer scienceOrganic chemistryProgramming languageMercury impact and mitigation studiesMarine animal studies overview
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