Biogeochemical dynamics in zero-valent iron columns: Implications for permeable reactive barriers

The impact of microbiological and geochemical processes has been a major co ncern for the long-term performance of permeable reactive barriers containi ng zero-valent iron (Fe-o). To evaluate potential biogeochemical impacts, l aboratory studies were performed over a 5-month period using columns contai ning a diverse microbial community. The conditions chosen for these experim ents were designed to simulate high concentrations of bicarbonate (17-33 mM HCO3-) and sulfate (7-20 mM SO42-) containing groundwater regimes. Groundw ater chemistry was found to significantly affect corrosion rates of Fe-o fi lings and resulted in the formation of a suite of mineral precipitates. HCO 3- ions in SO42-containing water were particularly corrosive to Fe-o, resul ting in the formation of ferrous carbonate and enhanced H-2 gas generation that stimulated the growth of microbial populations and increased SO42- red uction. Major mineral precipitates identified included lepidocrocite; akaga neite, mackinawite, magnetite/maghemite, goethite, siderite, and amorphous ferrous sulfide. Sulfide was formed as a result of microbial reduction of S O42- that became significant after about 2 months of column operations; Thi s study demonstrates that biogeochemical influences on the performance and reaction of Fe-o may be minimal in the short term (e.g., a few weeks or mon ths), necessitating longer-term operations to observe the effects of biogeo chemical reactions on the performance of Fe-o barriers. Although major fail ures of in-ground treatment barriers have not been problematic to date, the accumulation of iron oxyhydroxides, carbonates, and sulfides from biogeoch emical processes could reduce the reactivity and permeability of Fe-o beds, thereby decreasing treatment efficiency.