Hostname: page-component-8448b6f56d-c47g7 Total loading time: 0 Render date: 2024-04-23T06:30:38.790Z Has data issue: false hasContentIssue false
  • English
  • Français

Biogeochemical behaviour of plutonium during anoxic biostimulation of contaminated sediments

Published online by Cambridge University Press:  05 July 2018

R. L. Kimber ,
C. Boothman ,
P. Purdie ,
F. R. Livens  and
J. R. Lloyd
R. L. Kimber
Affiliation:
Williamson Research Centre for Molecular Environmental Science and Research Centre for Radwaste and Decommissioning, School of Earth, Atmospheric & Environmental Sciences, University of Manchester, Manchester M13 9PL, UK
C. Boothman
Affiliation:
Williamson Research Centre for Molecular Environmental Science and Research Centre for Radwaste and Decommissioning, School of Earth, Atmospheric & Environmental Sciences, University of Manchester, Manchester M13 9PL, UK
P. Purdie
Affiliation:
AWE PLC, Aldermaston, Berkshire RG7 4PR, UK
F. R. Livens
Affiliation:
Williamson Research Centre for Molecular Environmental Science and Research Centre for Radwaste and Decommissioning, School of Earth, Atmospheric & Environmental Sciences, University of Manchester, Manchester M13 9PL, UK Centre for Radiochemistry Research, School of Chemistry, University of Manchester, Manchester M13 9PL, UK
J. R. Lloyd
Affiliation:
Williamson Research Centre for Molecular Environmental Science and Research Centre for Radwaste and Decommissioning, School of Earth, Atmospheric & Environmental Sciences, University of Manchester, Manchester M13 9PL, UK
Get access Rights & Permissions [Opens in a new window]

Abstract

Understanding the biogeochemical behaviour of actinides in the environment is essential for the longterm stewardship of radionuclide contaminated land. Plutonium is of particular concern due its high radiotoxicity, long half-life and complex chemistry, with these factors contributing to the limited literature available on its environmental behaviour. Here, we investigate the biogeochemistry of Pu in contaminated soil as microbial processes have the potential to mobilize Pu through numerous mechanisms including the reduction of Pu(IV) to the potentially more mobile Pu(III). After the addition of glucose to stimulate microbial activities, there was a substantial shift in the 16S rRNA gene profile of the extant microbial communities between days 0 and 44 with an increase in Clostridium species, known glucose fermenters which have been reported to facilitate the reduction of Pu(IV) to Pu(III). A minor increase in Pu mobility was observed at day 44, returning to initial levels by day 118. The negligible change in Pu mobility, despite the onset of reducing conditions and changing mineralogy, would suggest the Pu is highly refractory. This information is important for developing remediation options for Pu-contaminated soils, suggesting that managing legacy Pu in situ may be preferred to mobilization via the stimulation of metal-reducing bacteria.

Keywords

plutoniumcontaminated landactinidesremediationmicrobial interactions
Type
Research Article
Information
Mineralogical Magazine , Volume 76 , Issue 3 , June 2012 , pp. 567 - 578
Copyright
Copyright © The Mineralogical Society of Great Britain and Ireland 2016

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Bethke, C.M., Sanford, R.A., Kirk, M.F., Jin, Q. and Flynn, T.M. (2011) The thermodynamic ladder in geomicrobiology. America. Journal of Science, 311, 183210 Google Scholar
Boukhalfa, H., Icopini, G.A., Reilly, S.D. and Neu, M.P. (2007) Plutonium(IV) reduction by the metalreducing bacteria Geobacter metallireducens GS15 and Shewanella oneidensis MR1. Applied and Environmenta. Microbiology, 73, 58975903 Google Scholar
Bulman, R.A. (1983) Complexation of transuranic elements: a look at factors which may enhance their biological availability. Pp. 105-113 in: Ecological Aspects of Radionuclide Release (P.J. Coughtrey, editor). Blackwell Scientific Publications, Oxford, UK.294 pp.Google Scholar
Choppin, G. (2007) Actinide speciation in the environment. Journal of Radioanalytical and Nuclea. Chemistry, 273, 695703 Google Scholar
Choppin, G.R., Bond, A.H. and Hromadka, P.M. (1997) Redox speciation of plutonium. Journal of Radioanalytical and Nuclea. Chemistry, 219, 203210 Google Scholar
Choppin, G.R. and Morgenstern, A. (2001) Distribution and movement of environmental plutonium. Pp. 91-105 in: Plutonium in the Environment (A. Kudo, editor). Proceedings of the Second International Symposium, Osaka, Japan.912November 1999. Radioactivity in the Environment, 1. Elsevier, Amsterdam.Google Scholar
Clark, D.L., Janecky, D.R. and Lane, L.J. (2006) Science-based cleanup of Rocky Flats. Physics Today, 59, 3440 CrossRefGoogle Scholar
Dobbin, P.S., Carter, J.P., San Juan, C.G.S., von Hobe, M., Powell, A.K. and Richardson, D.J. (1999) Dissimilatory Fe(III) reduction by Clostridium beijerinckii isolated from freshwater sediment using Fe(III) maltol enrichment. FEMS Microbiolog. Letters, 176, 131138 Google Scholar
Eden, P.A., Schmidt, T.M., Blakemore, R.P. and Pace, N.R. (1991) Phylogenetic analysis of Aquaspirillum magnetotacticum using polymerase chain reactionamplified 16s ribosomal-Rna-specific DNA. International Journal of Systemati. Bacteriology, 41, 324325 Google Scholar
Field, E.K., D’Imperio, S., Miller, A.R., VanEngelen, M.R., Gerlach, R., Lee, B.D., Apel, W.A. and Peyton, B.M. (2010) Application of molecular techniques to elucidate the influence of cellulosic waste on the bacterial community structure at a simulated low-level-radioactive-waste site. Applied and Environmenta. Microbiology, 76, 31063115 Google Scholar
Finneran, K.T., Johnsen, C.V. and Lovley, D.R. (2003) Rhodoferax ferrireducens sp nov., a psychrotolerant, facultatively anaerobic bacterium that oxidizes acetate with the reduction of Fe(III). International Journal of Systematic and Evolutionar. Microbiology, 53, 669673 Google Scholar
Francis, A.J. (2007) Microbial mobilization and immobilization of plutonium. Journal of Alloys an. Compounds, 444, 500505 CrossRefGoogle Scholar
Francis, A.J., Dodge, C.J. and Gillow, J.B. (2008) Reductive dissolution of Pu(IV) by Clostridium sp under anaerobic conditions. Environmental Scienc. Technology, 42, 23552360 CrossRefGoogle Scholar
Icopini, G.A., Boukhalfa, H. and Neu, M.P. (2007) Biological reduction of Np(V) and Np(V) citrate by metal-reducing bacteria. Environmental Scienc. Technology, 41, 27642769 CrossRefGoogle Scholar
Icopini, G.A., Lack, J.G., Hersman, L.E., Neu, M.P. and Boukhalfa, H. (2009) Plutonium(V/VI) reduction by the metal-reducing bacteria Geobacter metallireducens GS-15 and Shewanella oneidensis MR-1. Applied and Environmenta. Microbiology, 75, 36413647 Google Scholar
John, S.G., Ruggiero, C.E., Hersman, L.E., Tung, C.S. and Neu, M.P. (2001) Siderophore mediated plutonium accumulation by Microbacterium flavescens (JG-9). Environmental Science &. Technology, 35, 29422948 CrossRefGoogle Scholar
Kauffman, J.W., Laughlin, W.C. and Baldwin, R.A. (1986) Microbiological treatment of uranium-mine waters. Environmental Science &. Technology, 20, 243248 CrossRefGoogle Scholar
Law, G.T.W., Geissler, A., Boothman, C., Burke, I.T., Livens, F.R., Lloyd, J.R. and Morris, K. (2010a) Role of nitrate in conditioning aquifer sediments for technetium bioreduction. Environmental Science & Technology, 44, 150155 CrossRefGoogle Scholar
Law, G.T.W., Geissler, A., Lloyd, J.R., Livens, F.R., Boothman, C., Begg, J.D.C., Denecke, M.A., Rothe, J., Dardenne, K., Burke, I.T., Charnock, J.M. and Morris, K. (2010b) Geomicrobiological redox cycling of the transuranic element neptunium. Environmental Science & Technology, 44, 89248929 CrossRefGoogle Scholar
Litaor, M.I. and Ibrahim, S.A. (1996) Plutonium association with selected solid phases in soils of Rocky Flats, Colorado, using sequential extraction technique. Journal of Environmenta. Quality, 25, 11441152 CrossRefGoogle Scholar
Litaor, M.I., Barth, G., Zika, E.M., Litus, G., Moffitt, J. and Daniels, H. (1998) The behavior of radionuclides in the soils of Rocky Flats, Colorado. Journal of Environmental Radioactivity, 38, 1746.CrossRefGoogle Scholar
Lloyd, J.R., Yong, P. and Macaskie, L.E. (2000) Biological reduction and removal of Np(V) by two microorganisms. Environmental Science. Technology, 34, 12971301 CrossRefGoogle Scholar
Lloyd, J.R., Chesnes, J., Glasauer, S., Bunker, D.J., Livens, F.R. and Lovley, D.R. (2002) Reduction of actinides and fission products by Fe(III)-reducing bacteria. Geomicrobiolog. Journal, 19, 103120 Google Scholar
Lovley, D.R. and Phillips, E.J. (1988) Novel mode of microbial energy metabolism: organic carbon oxidation coupled to dissimilatory reduction of iron or manganese. Applied and Environmenta. Microbiology, 54, 14721480 Google ScholarPubMed
Lovley, D.R., Phillips, E.J.P., Gorby, Y.A. and Landa, E.R. (1991) Microbial reduction of uranium. Nature, 350, 413416 CrossRefGoogle Scholar
Lu, N., Kung, K.S., Mason, C.F.V., Triay, I.R., Cotter, C.R., Pappas, A.J. and Pappas, M.E.G. (1998) Removal of plutonium-239 and americium-241 from rocky flats soil by leaching. Environmental Scienc. Technology, 32, 370374 CrossRefGoogle Scholar
McCubbin, D., Leonard, K.S., Greenwood, R.C., and Taylor, B.R. (2004) Solid-solution partitioning of plutonium in surface waters at the Atomic Weapons Establishment Aldermaston (UK). Science of the Tota. Environment, 332, 203216 Google Scholar
McCullough, J., Hazen, T. and Benson, S. (1999) Bioremediation of Metals and Radionuclides: What It Is and How It Works. Lawrence Berkeley National Laboratory, Berkeley, California, USA.CrossRefGoogle Scholar
Mitchell, P.I., Vives i. Batlle, J., Downes, A.B., Condren, O.M., Leon Vintro, L. and Sanchez- Cabeza, J.A. (1995) Recent observations on the physico-chemical speciation of plutonium in the Irish Sea and the western Mediterranean. Applied Radiation an. Isotopes, 46, 11751190 CrossRefGoogle Scholar
Neu, M.P., Icopini, G.A. and Boukhalfa, H. (2005) Plutonium speciation affected by environmental bacteria. Radiochimic. Acta, 93, 705714 Google Scholar
Nuclear Decommissioning Authority (2010) Draft strategy published September 2010 for consultation. Nuclear Decommissioning Authority, Moor Row, UK.Google Scholar
Palmisano, A. and Hazen, T. (2003) Bioremediation of Metals and Radionuclides: What It Is and How It Works, second edition). Lawrence Berkeley National Laboratory, Berkeley, California.USA.Google Scholar
Panak, P.J. and Nitsche, H. (2001) Interaction of aerobic soil bacteria with plutonium(VI). Radiochimic. Acta, 89, 499504 Google Scholar
Reed, D.T., Lucchini, J.F., Aase, S.B. and Kropf, A.J. (2006) Reduction of plutonium(VI) in brine under subsurface conditions. Radiochimic. Acta, 94, 591597 Google Scholar
Renshaw, J.C., Butchins, L.J.C., Livens, F.R., May, I., Charnock, J.M. and Lloyd, J.R. (2005) Bioreduction of uranium: environmental implications of a pentavalent intermediate. Environmental Scienc. Technology, 39, 56575660 CrossRefGoogle Scholar
Renshaw, J.C., Law, N., Geissler, A., Livens, F.R. and Lloyd, J.R. (2009) Impact of the Fe(III)-reducing bacteria Geobacter sulfurreducens and Shewanella oneidensis on the speciation of plutonium. Biogeochemistry, 94, 191196 CrossRefGoogle Scholar
Rittmann, B.E., Banaszak, J.E. and Reed, D.T. (2002) Reduction of Np(V) and precipitation of Np(IV) by an anaerobic microbial consortium. Biodegradation, 13, 329342 CrossRefGoogle ScholarPubMed
Rusin, P.A., Quintana, L., Brainard, J.R., Strietelmeier, B.A., Tait, C.D., Ekberg, S.A., Palmer, P.D., Newton, T.W. and Clark, D.L. (1994) Solubilization of plutonium hydrous oxide by ironreducing bacteria. Environmental Scienc. Technology, 28, 16861690 CrossRefGoogle Scholar
Sanger, F., Nicklen, S. and Coulson, A.R. (1977) DNA sequencing with chain-terminating inhibitors. Proceedings of the National Academy of Sciences of the Unite. States of America, 74, 54635467 Google Scholar
Sholkovitz, E.R., Cochran, J.K. and Carey, A.E. (1983) Laboratory studies of the diagenesis and mobility of 239,240Pu and 137Cs in nearshore sediments. Geochimica et Cosmochimica Acta, 47, 13691379 CrossRefGoogle Scholar
Silva, R.J. and Nitsche, H. (1995) Actinide environmental chemistry. Radiochimica Acta, 70—1, 377-396.Google Scholar
Vishnivetskaya, T.A., Brandt, C.C., Madden, A.S., Drake, M.M., Kostka, J.E., Akob, D.M., Kusel, K. and Palumbo, A.V. (2010) Microbial community changes in response to ethanol or methanol amendments for U(VI) reduction. Applied and Environmenta. Microbiology, 76, 57285735 Google Scholar
Wilkins, M., Livens, F., Vaughan, D. and Lloyd, J. (2006) The impact of Fe(III)-reducing bacteria on uranium mobility. Biogeochemistry, 78, 125150 CrossRefGoogle Scholar
Wilkins, M.J., Livens, F.R., Vaughan, D.J., Beadle, I. and Lloyd, J.R. (2007) The influence of microbial redox cycling on radionuclide mobility in the subsurface at a low-level radioactive waste storage site. Geobiology, 5, 293301 CrossRefGoogle Scholar