TY - JOUR
T1 - Sulfidation of magnetite with incorporated uranium
AU - Townsend, Luke T.
AU - Morris, Katherine
AU - Harrison, Robert
AU - Schacherl, Bianca
AU - Vitova, Tonya
AU - Kovarik, Libor
AU - Pearce, Carolyn I.
AU - Mosselmans, J. Frederick W.
AU - Shaw, Samuel
N1 - Funding Information:
EPSRC funded the Doctoral Prize Fellowship for L.T.T. ( EP/R513131/1 ). EPSRC and Radioactive Waste Management Ltd. co-funded the PhD studentship to L.T.T. via the Next Generation Nuclear CDT ( EP/L015390/1 ). Diamond Light Source provided beamtime awards ( SP13559 , SP17376 , SP17243 ), and the authors thank Shu Hayama and Steve Parry for their beamline assistance. The authors thank the KIT Synchrotron Light Source for the provision of beamtime at the CAT-ACT beamline. The Institute for Beam Physics and Technology (KIT-IBPT) is acknowledged for the operation of the storage ring, the Karlsruhe Research Accelerator (KARA). A part of this work was performed at the William R. Wiley Environmental Molecular Science Laboratory (EMSL) (grid. 436923.9 ) sponsored by the US Department of Energy , Office of Biological and Environmental Research located at Pacific Northwest National Laboratory (PNNL) under science theme proposal 49774. The authors thank EMSL staff for their assistance. The authors also thank Paul Lythgoe and Thomas Neill for assistance with data acquisition.
Publisher Copyright:
© 2021 Elsevier Ltd
PY - 2021/8
Y1 - 2021/8
N2 - Uranium (U) is a radionuclide of key environmental interest due its abundance by mass within radioactive waste and presence in contaminated land scenarios. Ubiquitously present iron (oxyhydr)oxide mineral phases, such as (nano)magnetite, have been identified as candidates for immobilisation of U via incorporation into the mineral structure. Studies of how biogeochemical processes, such as sulfidation from the presence of sulfate-reducing bacteria, may affect iron (oxyhydr)oxides and impact radionuclide mobility are important in order to underpin geological disposal of radioactive waste and manage radioactively contaminated land. Here, this study utilised a highly controlled abiotic method for sulfidation of U(V) incorporated into nanomagnetite to determine the fate and speciation of U. Upon sulfidation, transient release of U into solution occurred (∼8.6 % total U) for up to 3 days, despite the highly reducing conditions. As the system evolved, lepidocrocite was observed to form over a period of days to weeks. After 10 months, XAS and geochemical data showed all U was partitioned to the solid phase, as both nanoparticulate uraninite (U(IV)O2) and a percentage of retained U(V). Further EXAFS analysis showed incorporation of the residual U(V) fraction into an iron (oxyhydr)oxide mineral phase, likely nanomagnetite or lepidocrocite. Overall, these results provide new insights into the stability of U(V) incorporated iron (oxyhydr)oxides during sulfidation, confirming the longer term retention of U in the solid phase under complex, environmentally relevant conditions.
AB - Uranium (U) is a radionuclide of key environmental interest due its abundance by mass within radioactive waste and presence in contaminated land scenarios. Ubiquitously present iron (oxyhydr)oxide mineral phases, such as (nano)magnetite, have been identified as candidates for immobilisation of U via incorporation into the mineral structure. Studies of how biogeochemical processes, such as sulfidation from the presence of sulfate-reducing bacteria, may affect iron (oxyhydr)oxides and impact radionuclide mobility are important in order to underpin geological disposal of radioactive waste and manage radioactively contaminated land. Here, this study utilised a highly controlled abiotic method for sulfidation of U(V) incorporated into nanomagnetite to determine the fate and speciation of U. Upon sulfidation, transient release of U into solution occurred (∼8.6 % total U) for up to 3 days, despite the highly reducing conditions. As the system evolved, lepidocrocite was observed to form over a period of days to weeks. After 10 months, XAS and geochemical data showed all U was partitioned to the solid phase, as both nanoparticulate uraninite (U(IV)O2) and a percentage of retained U(V). Further EXAFS analysis showed incorporation of the residual U(V) fraction into an iron (oxyhydr)oxide mineral phase, likely nanomagnetite or lepidocrocite. Overall, these results provide new insights into the stability of U(V) incorporated iron (oxyhydr)oxides during sulfidation, confirming the longer term retention of U in the solid phase under complex, environmentally relevant conditions.
KW - GDF
KW - HR-XANES
KW - Iron (oxyhydr)oxide
KW - Sulfidation
KW - Uranium
KW - XAS
UR - https://www.research.manchester.ac.uk/portal/en/publications/sulfidation-of-magnetite-with-incorporated-uranium(c844f44c-b775-4cf5-8fe9-f5f35c6feee7).html
U2 - 10.1016/j.chemosphere.2021.130117
DO - 10.1016/j.chemosphere.2021.130117
M3 - Article
SN - 0045-6535
VL - 276
SP - 130117
JO - Chemosphere
JF - Chemosphere
M1 - 130117
ER -