Bioreduction of Uranium:  Environmental Implications of a Pentavalent Intermediate

Renshaw, Joanna C.; Butchins, Laura J C; Livens, Francis R.; May, Iain; Charnock, John; Lloyd, Jonathan R.

doi:10.1021/es048232b

Cited by 207 publications

(226 citation statements)

References 23 publications

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“…[64,65] With this study, the potential of bulk reactions with selected additives for providing mechanistic information on aqueous contaminant removal has been demonstrated. This applicable technique can be very useful to obtain qualitative information on Fe 0 removal mechanisms for several contaminants; particularly for other radionuclides, metals and some organics which are known to interact with iron oxide.…”

Section: Discussionmentioning

confidence: 99%

“…At Bodo Canyon Site (Durango, Colorado) uranium was present nearly exclusively as U(VI). [64,65] Another important fact in favor of U(VI) co-precipitation with aging corrosion products is given by Morrison et al [22] , who conducted laboratory column experiments under anoxic conditions and could not accurately model their results according to reductive precipitation or U(VI) adsorption onto Fe(III) oxides. They stated that "while a reductive precipitation mechanism is not inconsistent with the results of the laboratory column experiment, the decrease in Eh in the bulk is suspect.…”

Section: Arguments For U(vi) Co-precipitation With Aging Corrosion Prmentioning

confidence: 99%

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Mechanism of uranium removal from the aqueous solution by elemental iron

Noubactep¹,

Schöner

Meinrath

2006

Journal of Hazardous Materials

124

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The effectiveness of elemental iron (Fe 0 ) to remove uranium (U) from the aqueous phase has been demonstrated. While the mitigation effect is sure, discrepancies in the removal mechanism have been reported. The objective of this study was to investigate the mechanism of U(VI) removal from aqueous phases by Fe 0 . For this purpose a systematic sequence of bulk experiments was conducted to characterize the effects of the availability and the abundance of corrosion products on U(VI) removal. Results indicated that U(VI) removal reactions did not primary occur at the surface of the metallic iron. It is determined that U(VI) co-precipitation with aging corrosion products is a plausible explanation for the irreversible fixation under experimental conditions. Results of XRD analyses did no show any U phases, whereas SEM-EDX analyses showed that U tended to associate with rusted areas on the surface of Fe 0 .Recovering U with different leaching solutions varied upon the dissolution capacity of the individual solutions for corrosion products, showing that the irreversibility of the removal 2 depends on the stability of the corrosion products. U(VI) co-precipitation as removal mechanism enables a better discussion of reported discrepancies.

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Section: Discussionmentioning

confidence: 99%

Section: Arguments For U(vi) Co-precipitation With Aging Corrosion Prmentioning

confidence: 99%

Mechanism of uranium removal from the aqueous solution by elemental iron

Noubactep¹,

Schöner

Meinrath

2006

Journal of Hazardous Materials

124

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“…Subsequent studies have also reported biogenic uraninite particle sizes in the 2 to 10 nm range and slight but significant contraction of the first U-U shell (Renshaw et al 2005;Singer et al 2006;Senko et al 2007;Burgos et al 2008;Komlos et al 2008). Similar results have been reported for uraninite nanoparticles produced by abiotic reduction of U(VI) by green rust (O'Loughlin et al 2003).…”

Section: Structure and Composition Of Biogenic Uraninitementioning

confidence: 91%

“…U(V) is unstable as an aqueous complex (Nagaishi et al 1996), and it is therefore possible that enzymatic reduction proceeds from U(VI) to U(V), followed by disproportionation to U(IV) and U(VI). Tentative evidence in support of this mechanism has been provided by Renshaw et al (2005) and Grossmann et al (2007), but further work is required to unambiguously demonstrate the relevance of this reduction pathway.…”

Section: Biological Reduction and Uraninite Precipitationmentioning

confidence: 98%

Biogenic Uraninite Nanoparticles and Their Importance for Uranium Remediation

et al. 2008

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Biogenic uraninite is of interest to geoscientists for its importance to bioremediation strategies, remarkably small particle size, and biological origin. Recent studies have begun to illuminate the chemical/structural complexities of this important natural nanomaterial. Intriguingly, in spite of its incredibly diminutive size, the molecular-scale structure, energetics, and surfacearea-normalized dissolution rates of hydrated biogenic uraninite appear to be similar to those of coarser-particle, abiotic, stoichiometric UO 2 . These findings have important implications for the role of size as a moderator of nanoparticle aqueous reactivity and for the bioremediation of subsurface U(VI) contamination.

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“…Natural attenuation processes such as bacterial reductive/precipitation and immobilization of soluble uranium is gaining much interest (Dodge and Francis, 2008). For example, dissimilatory metal-reducing microorganisms have been investigated for their capability to selectively remove uranium from aqueous solutions (Lovley et al, 1992;Renshaw et al, 2005). These bacteria can use U(VI) as an electron acceptor thereby reducing soluble U(VI) to the precipitable tetravalent state [U(IV)] (Lovley et al, 1992;Lloyd and Renshaw, 2005;.…”

Section: Introductionmentioning

confidence: 99%

Uranium(VI) reduction and removal by high performing purified anaerobic cultures from mine soil

Chabalala

Chirwa

2010

Chemosphere

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Biological uranium reduction was investigated using bacteria isolated from a uranium mine in Limpopo, South Africa. Background uranium concentration in soil from the mine was determined to be 168 mg kg -1 much higher than the typical background uranium concentration in natural soils (0.30-11.7 mg kg -1 ). Therefore it was expected that the bacteria isolated from the site were resistant to U(VI) toxicity.Preliminary studies using a non-purified consortium from the mine soil showed that

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Bioreduction of Uranium: Environmental Implications of a Pentavalent Intermediate

Cited by 207 publications

References 23 publications

Mechanism of uranium removal from the aqueous solution by elemental iron

Mechanism of uranium removal from the aqueous solution by elemental iron

Biogenic Uraninite Nanoparticles and Their Importance for Uranium Remediation

Uranium(VI) reduction and removal by high performing purified anaerobic cultures from mine soil

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