AI Article Synopsis
- In CO2-rich environments with oxygen, negatively charged uranyl complexes are thought to have low adsorption on negatively charged surfaces like bacteria.
- Our experiments measured how much uranium adsorbs onto Bacillus subtilis at various pH levels and bacterial concentrations, finding significant adsorption under all tested conditions.
- Thermodynamic modeling indicates that different stable uranyl species can form complexes on bacterial walls, suggesting that current predictions about uranium movement in the environment may need to be re-evaluated.
Article Abstract
In oxygenated, CO2-rich systems, negatively charged uranyl complexes dominate the aqueous uranium speciation, and it is commonly assumed that these complexes exhibit negligible adsorption onto negatively charged surfaces such as bacteria. We measured the adsorption of 4.2 x 10(-6) M aqueous uranium onto Bacillus subtilis from pH 1.5 to 9 and with wet weight bacterial concentrations from 0.125 to 0.5 g/L. Experiments were performed in the presence and absence of dissolved CO2, and additional experiments were performed in the presence of dissolved CO2 and Ca. We observed extensive uranium adsorption onto the bacterial surface under all conditions. Thermodynamic modeling of the data suggests that uranylhydroxide, uranyl-carbonate, and calcium-uranylcarbonate species each can form stable surface complexes on the bacterial cell wall. These results could dramatically alter predictions of uranium mobility in near-surface environments.
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| http://dx.doi.org/10.1021/es047957c | DOI Listing |
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