Impacts of Forest Fire Ash on Aquatic Mercury Cycling

Han Han Li, Martin Tsz Ki Tsui, Peijia Ku, Huan Chen, Ziyu Yin, Randy A. Dahlgren, Sanjai J. Parikh, Jianjun Wei, Tham C. Hoang, Alex T. Chow, Zhang Cheng, Xue Mei Zhu

Research output: Contribution to journalArticlepeer-review

16 Scopus citations

Abstract

Mercury (Hg) is a ubiquitous contaminant in the environment and its methylated form, methylmercury (MeHg), poses a worldwide health concern for humans and wildlife, primarily through fish consumption. Global production of forest fire ash, derived from wildfires and prescribed burns, is rapidly increasing due to a warming climate, but their interactions with aqueous and sedimentary Hg are poorly understood. Herein, we compared the differences of wildfire ash with activated carbon and biochar on the sorption of aqueous inorganic Hg and sedimentary Hg methylation. Sorption of aqueous inorganic Hg was greatest for wildfire ash materials (up to 0.21 μg g-1 or 2.2 μg g-1 C) among all of the solid sorbents evaluated. A similar Hg adsorption mechanism for activated carbon, biochar made of walnut, and wildfire ash was found that involves the formation of complexes between Hg and oxygen-containing functional groups, especially the -COO group. Notably, increasing dissolved organic matter from 2.4 to 70 mg C L-1 remarkably reduced Hg sorption (up to 40% reduction) and increased the time required to reach Hg-sorbent pseudo-equilibrium. Surprisingly, biochar and wildfire ash, but not activated carbon, stimulated MeHg production during anoxic sediment incubation, possibly due to the release of labile organic matter. Overall, our study indicates that while wildfire ash can sequester aqueous Hg, the leaching of its labile organic matter may promote production of toxic MeHg in anoxic sediments, which has an important implication for potential MeHg contamination in downstream aquatic ecosystems after wildfires.

Original languageEnglish
Pages (from-to)11835-11844
Number of pages10
JournalEnvironmental Science and Technology
Volume56
Issue number16
DOIs
StatePublished - Aug 16 2022

Funding

The authors acknowledge the funding support by the China Scholarship Council to H.L. for undertaking this overseas exchange program. This study was financially supported by the National Science Foundation awards (EAR-1711642 and CBET-1917156) and the National Institute of Food and Agriculture award (2018-67019-27795) both to M.T.-K.T. and A.T.C.

Keywords

  • activated carbon
  • aqueous mercury sorption
  • biochar
  • mercury methylation
  • wildfire ash

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