2015
DOI: 10.1016/j.gca.2015.02.006
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Effects of aqueous uranyl speciation on the kinetics of microbial uranium reduction

Abstract: The ability to predict the success of the microbial reduction of soluble U(VI) to highly insoluble U(IV) as an in situ bioremediation strategy is complicated by the wide range of geochemical conditions at contaminated sites and the strong influence of aqueous uranyl speciation on the bioavailability and toxicity of U(VI) to metal-reducing bacteria. To determine the effects of aqueous uranyl speciation on uranium bioreduction kinetics, incubations and viability assays with Shewanella putrefaciens strain 200 wer… Show more

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Cited by 50 publications
(37 citation statements)
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“…It is important to understand how these different U species interact with bacterial cellular surfaces, especially for designing biological wastewater treatment systems. However, studies evaluating the effect of aqueous U speciation have been largely limited to biosorption, bioaccumulation, and bioreduction (9,15,16,20).…”
Section: (Oh)]mentioning
confidence: 99%
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“…It is important to understand how these different U species interact with bacterial cellular surfaces, especially for designing biological wastewater treatment systems. However, studies evaluating the effect of aqueous U speciation have been largely limited to biosorption, bioaccumulation, and bioreduction (9,15,16,20).…”
Section: (Oh)]mentioning
confidence: 99%
“…U forms aqueous species as a result of complexation with ligands under different pH conditions (14). In open atmospheric systems, under oxygenic conditions, and with pH values lower than 3, U(VI) is present exclusively in the form of hexavalent uranyl cation, UO 2 2ϩ , which is the most bioavailable form of U (15,16 predominate (17-19). It is important to understand how these different U species interact with bacterial cellular surfaces, especially for designing biological wastewater treatment systems.…”
mentioning
confidence: 99%
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“…Cytochrome c3 has a mid-point redox potential near −300 mV versus SHE (standard hydrogen electrode) at 25°C (Niki et al, 1984), while the U(VI)-U(IV) couple has a mid-point potential of +334 mV versus SHE of dissolved inorganic carbon (DIC) and with a wide range of pH is of paramount importance for understanding microbial reduction of U(VI), since different U(VI) species could have different susceptibilities of being reduced based on their bioavailability. A decrease in U(VI) reduction rate with increasing DIC concentration, along with sensitivity towards pH, has been well documented in the literature (Belli et al, 2015;Bernhard, Geipel, Brendler, & Nitsche, 1998;Brooks et al, 2003;Croteau, Fuller, Cain, Campbell, & Aiken, 2016;Drobot et al, 2015;Guillauont et al, 2003;Jones et al, 2015;Sheng & Fein, 2014;Ulrich et al, 2011).…”
Section: Electron Flow and Speciationmentioning
confidence: 71%
“…Carbonate is a key ligand in natural environments, and it influences the speciation of uranium (Clark, Hobart, & Neu, 1995;Langmuir, 1978;Stumm & Morgan, 1996), along with being an important pH buffer. Although U(VI) speciation and bioavailability of U(VI) in its different complexes have been studied for decades in isolation (Belli, DiChristina, Cappellen, & Taillefert, 2015;Brooks et al, 2003;Murphy & Shock, 1999;Stewart, Amos, Nico, & Fendorf, 2011;Sheng & Fein, 2014;Ulrich, Veeramani, Latmani, & Giammar, 2011), the connections between aqueous uranyl speciation, and electron partitioning between respiration & fermentation during U(VI) bioreduction were seldom studied. In sulfate-reducing conditions, the availability of the electron acceptor affects how electrons from the electron donor (lactate in our case) are distributed among fermentation and respiration end products.…”
mentioning
confidence: 99%