posted on 2011-10-15, 00:00authored byKate M. Campbell, Harish Veeramani, Kai-Uwe Ulrich, Lisa Y. Blue, Daniel E. Giammar, Rizlan Bernier-Latmani, Joanne E. Stubbs, Elena Suvorova, Steve Yabusaki, Juan
S. Lezama-Pacheco, Apurva Mehta, Philip E. Long, John R. Bargar
Reductive bioremediation is currently being explored as a possible
strategy for uranium-contaminated aquifers such as the Old Rifle site
(Colorado). The stability of U(IV) phases under oxidizing conditions
is key to the performance of this procedure. An in situ method was
developed to study oxidative dissolution of biogenic uraninite (UO2), a desirable U(VI) bioreduction product, in the Old Rifle,
CO, aquifer under different variable oxygen conditions. Overall uranium
loss rates were 50–100 times slower than laboratory rates.
After accounting for molecular diffusion through the sample holders,
a reactive transport model using laboratory dissolution rates was
able to predict overall uranium loss. The presence of biomass further
retarded diffusion and oxidation rates. These results confirm the
importance of diffusion in controlling in-aquifer U(IV) oxidation
rates. Upon retrieval, uraninite was found to be free of U(VI), indicating
dissolution occurred via oxidation and removal of surface atoms. Interaction
of groundwater solutes such as Ca2+ or silicate with uraninite
surfaces also may retard in-aquifer U loss rates. These results indicate
that the prolonged stability of U(IV) species in aquifers is strongly
influenced by permeability, the presence of bacterial cells and cell
exudates, and groundwater geochemistry.