McBeth, J. M., Lloyd, J. R., Law, G. T. W., Livens, F. R., Burke, I. T., Morris, K. (2011) Redox interactions of technetium with iron-bearing minerals. Mineralogical Magazine, 75 (4) 2419-2430 doi:10.1180/minmag.2011.075.4.2419
| Reference Type | Journal (article/letter/editorial) | ||
|---|---|---|---|
| Title | Redox interactions of technetium with iron-bearing minerals | ||
| Journal | Mineralogical Magazine | ||
| Authors | McBeth, J. M. | Author | |
| Lloyd, J. R. | Author | ||
| Law, G. T. W. | Author | ||
| Livens, F. R. | Author | ||
| Burke, I. T. | Author | ||
| Morris, K. | Author | ||
| Year | 2011 (August) | Volume | 75 |
| Issue | 4 | ||
| Publisher | Mineralogical Society | ||
| DOI | doi:10.1180/minmag.2011.075.4.2419Search in ResearchGate | ||
| Generate Citation Formats | |||
| Mindat Ref. ID | 244162 | Long-form Identifier | mindat:1:5:244162:1 |
| GUID | 0 | ||
| Full Reference | McBeth, J. M., Lloyd, J. R., Law, G. T. W., Livens, F. R., Burke, I. T., Morris, K. (2011) Redox interactions of technetium with iron-bearing minerals. Mineralogical Magazine, 75 (4) 2419-2430 doi:10.1180/minmag.2011.075.4.2419 | ||
| Plain Text | McBeth, J. M., Lloyd, J. R., Law, G. T. W., Livens, F. R., Burke, I. T., Morris, K. (2011) Redox interactions of technetium with iron-bearing minerals. Mineralogical Magazine, 75 (4) 2419-2430 doi:10.1180/minmag.2011.075.4.2419 | ||
| Abstract/Notes | AbstractIron minerals influence the environmental redox behaviour and mobility of metals including the long-lived radionuclide technetium. Technetium is highly mobile in its oxidized form pertechnetate (Tc(VII)O4–), however, when it is reduced to Tc(IV) it immobilizes readily via precipitation or sorption. In low concentration tracer experiments, and in higher concentration XAS experiments, pertechnetate was added to samples of biogenic and abiotically synthesized Fe(II)-bearing minerals (bio-magnetite, bio-vivianite, bio-siderite and an abiotically precipitated Fe(II) gel). Each mineral scavenged different quantities of Tc(VII) from solution with essentially complete removal in Fe(II)-gel and bio-magnetite systems and with 84±4% removal onto bio-siderite and 68±5% removal onto bio-vivianite over 45 days. In select, higher concentration, Tc XAS experiments, XANES spectra showed reductive precipitation to Tc(IV) in all samples. Furthermore, EXAFS spectra for bio-siderite, bio-vivianite and Fe(II)-gel showed that Tc(IV) was present as short range ordered hydrous Tc(IV)O2-like phases in the minerals and for some systems suggested possible incorporation in an octahedral coordination environment. Low concentration reoxidation experiments with air-, and in the case of the Fe(II) gel, nitrate-oxidation of the Tc(IV)-labelled samples resulted in only partial remobilization of Tc. Upon exposure to air, the Tc bound to the Fe-minerals was resistant to oxidative remobilization with a maximum of ∼15% Tc remobilized in the bio-vivianite system after 45 days of air exposure. Nitrate mediated oxidation of Fe(II)-gel inoculated with a stable consortium of nitrate-reducing, Fe(II)-oxidizing bacteria showed only 3.8±0.4% remobilization of reduced Tc(IV), again highlighting the recalcitrance of Tc(IV) to oxidative remobilization in Fe-bearing systems. The resultant XANES spectra of the reoxidized minerals showed Tc(IV)-like spectra in the reoxidized Fe-phases. Overall, this study highlights the role that Fe-bearing biogenic mineral phases have in controlling reductive scavenging of Tc(VII) to hydrous TcO2-like phases onto a range of Fe(II)-bearing minerals. In addition, it suggests that on reoxidation of these phases, Fe-bound Tc(IV) may be octahedrally coordinated and is largely recalcitrant to reoxidation over medium-term timescales. This has implications when considering remediation approaches and in predictions of the long-term fate of Tc in the nuclear legacy. | ||
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