4.7 Article

Dissolved organic matter reduces the effectiveness of sorbents for mercury removal

Journal

SCIENCE OF THE TOTAL ENVIRONMENT
Volume 690, Issue -, Pages 410-416

Publisher

ELSEVIER
DOI: 10.1016/j.scitotenv.2019.07.001

Keywords

Mercury; Contamination; Remediation; Sorbents; Organic matter

Funding

  1. URS\CH2M Oak Ridge LLC (UCOR)
  2. Mercury Technology Development Program at Oak Ridge National Laboratory (ORNL)
  3. Oak Ridge Office of Environmental Management, U.S. Department of Energy (DOE)
  4. DOE [DE-AC05-00OR22725]
  5. USDA National Institute of Food and Agriculture [2017-67021-26599]
  6. Hatch Project [1012359]

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Mercury (Hg) contamination of soils and sediments impacts numerous environments worldwide and constitutes a challenging remediation problem. In this study, we evaluate the impact of dissolved organic matter (DOM) on the effectiveness of eight sorbent materials considered for Hg remediation in soils and sediments. The materials include both engineered and unmodified materials based on carbon, clays, mesoporous silica and a copper alloy. Initially, we investigated the kinetics of Hg(II) complexation with DOM fora series of Hg:DOM ratios. Steady-state Hg-DOM complexation occurred within 48 to 120 h, taking longer time at higher Hg:DOC (dissolved organic carbon) molar ratios. In subsequent equilibrium experiments, Hg(II) was equilibrated with DOM at a defined Hg:DOC molar ratio (2.4.10(-6)) for 170 h and used in batch experiments to determine the effect of DOM on Hg partition coefficients and sorption isotherms by comparing Hg(II) and Hg-DOM. Hg sorption capacities of all sorbents were severely limited in the presence of DOM as a competing ligand. Thiol-SAMMS (R), SediMite (TM) and pine biochar were most effective in reducing Hg concentrations. While pine biochar and lignin-derived carbon processed at high temperatures released negligible amounts of anions into solution, leaching of sulfate and chloride was observed for most engineered sorbent materials. Sulfate may stimulate microbial communities harboring sulfate reducing bacteria, which are considered one of the primary drivers of microbial mercury methylation in the environment. The results highlight potential challenges arising from the application of sorbents for Hg remediation in the field. (C) 2019 Elsevier B.V. All rights reserved.

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