Bisulfite reduction of soil iron for the reductive degradation of trichloroethylene.

This study explored the potential reactivities of various reductants in inducing subsurface TCE degradation in natural soils. It was found that bisulfite (HSO 3 −) exhibited the ability to induce reduction in soil iron minerals, and increase the degradation of TCE in the soil slurry system; however, no TCE degradation occurred in the aqueous system. The role of TCE degradation by soil constituents, such as major soil mineral elements, Fe and humic acid (HA) on HSO 3 −, was examined in aqueous phase. It was seen that by themselves, the presence of Fe3+, HA, Fe 2 O 3 , FeOOH, and Fe 3 O 4 did not result in substantial TCE removals. However, the presence of HSO 3 − can significantly induce iron reduction, producing a reducing condition that can result in complete TCE degradation. Furthermore, the reductive pathway was identified as the dominant degradation route via electron scavenging with periodate ion. To demonstrate the applicability of HSO 3 − reduction enhancement, a HSO 3 −/TCE mixed solution was flushed through a soil column, with gradually increased HSO 3 − concentrations, at a fixed flow rate, and also with varied flushing rates at a fixed HSO 3 − concentration. Based on our study, a 10 mM HSO 3 − solution may be effective for some environmental sites; however, each site requires specific evaluation based on contaminant concentrations and subsurface conditions. [Display omitted] • Bisulfite (HSO 3 −) reduced soils can induce TCE degradation. • The HSO 3 − can significantly induce soil iron reduction to result in complete TCE degradation. • HSO 3 − in soils can produce a reductive route in degrading TCE. • Flushing a HSO 3 −/TCE solution through soil media can achieve complete TCE degradation. • 10 mM HSO 3 − or greater is recommended for in situ injection into the subsurface for TCE degradation. [ABSTRACT FROM AUTHOR]