Objective

Representative remedial drivers for metal contaminated soils.

There are thousands of metal-contaminated sites on Department of Defense (DoD) lands that are awaiting cleanup and closure. Lead (Pb), arsenic (As), chromium (Cr), and cadmium (Cd) are of particular concern since these metals drive risk-based remedial decisions for soils at DoD sites. Contaminated soils that lack the ability to naturally sequester and decrease toxic metal bioavailability will remain a human health risk in their natural state. In situ chemical manipulation strategies are an attractive alternative to ex situ methods because the redox state and chemical speciation of metals can easily be altered through changes in soil geochemistry. Despite the success of chemical manipulation strategies for immobilizing Pb in various subsurface environments, chemical manipulation strategies have not been investigated to a significant extent on a vast array of DoD soils or priority contaminants. The rates and mechanisms that control enhanced metal sequestration and decreased bioavailability are largely unknown as are the costs associated with risk-reduction due to decreased bioaccessibility of metals in amended soils.

The overall objective of this project was to develop an improved understanding and predictive capability of the enhanced immobilization and decreased bioaccessibility of hazardous metals in soil as a result of novel chemical amendment strategies.