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Mercury Contaminated Sediment Sites- An Evaluation of Remedial Options
Citation:
Randall, P. AND S. Chattopadhyay. Mercury Contaminated Sediment Sites- An Evaluation of Remedial Options. M.S. Goldberg and E.K. Silbergeld (ed.), ENVIRONMENTAL RESEARCH. ELSEVIER, AMSTERDAM, Holland, 125:131-149, (2013).
Impact/Purpose:
In remedial investigations and screening of potential alternatives, the environmental manager may consider the following approaches for mercury-contaminated sites. This review paper discusses remedial options for Hg-contaminated sediment sites. In addition, this paper discusses mercury sorption and desorption processes, reviews mathematical models available to predict the fate and transport of Hg in the environment, and reviews selected case studies.
Description:
Mercury (Hg) is a naturally-occurring element that is ubiquitous in the aquatic environment. Though efforts have been made in recent years to decrease Hg emissions, historically-emitted Hg can be retained in the sediments of aquatic bodies where they may be slowly converted to methylmercury (MeHg). Consequently, Hg in historically-contaminated sediments can result in high levels of significant exposure for aquatic species, wildlife and human populations consuming fish. Even if source control of contaminated wastewater is achievable, it may take a very long time, perhaps decades, for Hg-contaminated aquatic systems to reach relatively safe Hg levels in both water and surface sediment naturally. It may take even longer if Hg is present at higher concentration levels in deep sediment. Hg contaminated sediment results from previous releases or ongoing contributions from sources that are difficult to identify. Due to human activities or physical, chemical, or biological processes (e.g., hydrodynamic flows, bioturbation, molecular diffusion, and chemical transformation), the buried Hg can be remobilized into the overlying water. Hg speciation in the water column and sediments critically affect the reactivity (i.e., conversion of inorganic Hg (II) to MeHg), transport, and its exposure to living organisms. Also, geochemical conditions affect the activity methylating bacteria and its availability for methylation. This review paper discusses remedial considerations (e.g., key chemical factors in fate and transport of Hg, source characterization and control, environmental management procedures, remediation options, modeling tools) and includes practical case studies for cleaning up Hg-contaminated sediment sites.
