Abstract
ConspectusMercury (Hg) is a global environmental contaminant. Major anthropogenic sources of Hg emission include gold mining and the burning of fossil fuels. Once deposited in aquatic environments, Hg can undergo redox reactions, form complexes with ligands, and adsorb onto particles. It can also be methylated by microorganisms. Mercury, especially its methylated form methylmercury, can be taken up by organisms, where it bioaccumulates and biomagnifies in the food chain, leading to detrimental effects on ecosystem and human health. In support of the recently enforced Minamata Convention on Mercury, a legally binding international convention aimed at reducing the anthropogenic emission of - and human exposure to - Hg, its global biogeochemical cycle must be understood. Thus, a detailed understanding of the molecular-level interactions of Hg is crucial.The ongoing rapid development of hardware and methods has brought computational chemistry to a point that it can usefully inform environmental science. This is particularly true for Hg, which is difficult to handle experimentally due to its ultratrace concentrations in the environment and its toxicity. The current account provides a synopsis of the application of computational chemistry to filling several major knowledge gaps in environmental Hg chemistry that have not been adequately addressed experimentally.Environmental Hg chemistry requires defining the factors that determine the relative affinities of different ligands for Hg species, as they are critical for understanding its speciation, transformation and bioaccumulation in the environment. Formation constants and the nature of bonding have been determined computationally for environmentally relevant Hg(II) complexes such as chlorides, hydroxides, sulfides and selenides, in various physical phases. Quantum chemistry has been used to determine the driving forces behind the speciation of Hg with hydrochalcogenide and halide ligands. Of particular importance is the detailed characterization of solvation effects. Indeed, the aqueous phase reverses trends in affinities found computationally in the gas phase. Computation has also been used to investigate complexes of methylmercury with (seleno)amino acids, providing a molecular-level understanding of the toxicological antagonism between Hg and selenium (Se). Furthermore, evidence is emerging that ice surfaces play an important role in Hg transport and transformation in polar and alpine regions. Therefore, the diffusion of Hg and its ions through an idealized ice surface has been characterized.Microorganisms are major players in environmental mercury cycling. Some methylate inorganic Hg species, whereas others demethylate methylmercury. Quantum chemistry has been used to investigate catalytic mechanisms of enzymatic Hg methylation and demethylation. The complex interplay between the myriad chemical reactions and transport properties both in and outside microbial cells determines net biogeochemical cycling. Prospects for scaling up molecular work to obtain a mechanistic understanding of Hg cycling with comprehensive multiscale biogeochemical modeling are also discussed.
Original language | English |
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Pages (from-to) | 379-388 |
Number of pages | 10 |
Journal | Accounts of Chemical Research |
Volume | 52 |
Issue number | 2 |
DOIs | |
State | Published - Feb 19 2019 |
Funding
Three research groups at two different institutions have come together for this Account. Initially, we had corresponded about failure to cite each other’s papers, but we decided to turn this experience around. The result is this Account: “When handed a lemon, make lemonade!” G.S. and F.W. acknowledge funding from NSERC, and F.W. from the Canada Research Chairs program. J.M.P., D.R., and J.C.S. acknowledge support from the US Department of Energy (DOE), Office of Science, Office of Biological and Environmental Research, through the Mercury Scientific Focus Area at Oak Ridge National Laboratory (ORNL) and the Subsurface Biogeochemical Research (SBR) program at the University of Tennessee Knoxville and ORNL through Grants DE-SC0004895 and DE-SC0016478 from the US Department of Energy (DOE). ORNL is managed by UT-Battelle, LLC, for the US Department of Energy under contract DE-AC05-00OR22725. SJC was supported by NIH/NIGMS-IMSD Grant No. R25GM086761 and a National Science Foundation Graduate Research Fellowship under Grant No. 2017219379.
Funders | Funder number |
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NIGMS-IMSD | R25GM086761 |
National Science Foundation | 2017219379 |
National Institutes of Health | |
U.S. Department of Energy | |
Office of Science | |
Biological and Environmental Research | |
Oak Ridge National Laboratory | |
University of Tennessee, Knoxville | DE-AC05-00OR22725, DE-SC0004895, DE-SC0016478 |
Natural Sciences and Engineering Research Council of Canada | |
Canada Research Chairs |