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TitleControls on uranium, rare earth element, and radionuclide mobility at the decommissioned Bicroft Uranium Mine, Ontario
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AuthorParsons, M B; Friske, P W B; Laidlow, A M; Jamieson, H E
SourceGeological Survey of Canada, Scientific Presentation 24, 2014, 1 sheet, https://doi.org/10.4095/293623
Year2014
PublisherNatural Resources Canada
Meeting40th Atlantic Geoscience Society Colloquium and Annual Meeting; Wolfville; CA; February 7-9, 2014
Documentserial
Lang.English
Mediadigital; on-line
RelatedThis publication is related to Parsons, M B; Friske, P W B; Laidlow, A M; Jamieson, H E; (2014). Controls on uranium, rare earth element, and radionuclide mobility at the decommissioned Bicroft Uranium Mine, Ontario; Controls on uranium, rare earth element, and radionuclide mobility at the decommissioned Bicroft Uranium Mine, Ontario; Controls on uranium, rare earth element, and radionuclide mobility at the decommissioned Bicroft Uranium Mine, Ontario; Controls on uranium, rare earth element, and radionuclide mobility at the decommissioned Bicroft Uranium Mine, Ontario, Atlantic Geoscience Society 40th Colloquium and Annual Meeting, program with abstracts
File formatpdf
ProvinceOntario
NTS31D/16
Lat/Long WENS-78.0500 -78.0333 45.0000 44.9833
Subjectseconomic geology; geochemistry; metallic minerals; environmental geology; uranium; uranium deposits; radionuclides; tailings; tailings analyses; tailings geochemistry; radioactivity; radioactive waste; surface waters; lake sediment geochemistry; lake water geochemistry; lake sediments; lake water; iron; hydroxides; thorium; Bicroft Mine; rare earth elements; rare earth element analyses
Illustrationslocation maps; photographs; plots; graphs
ProgramTools for environmental impacts and adaptation for metal mining, Environmental Geoscience
Image
Released2014 04 09
AbstractUranium ores have been mined in Canada since the 1930s, resulting in the production of approximately 214 million tonnes of mill tailings. These tailings may pose a risk to ecosystems and human health because of their long-lived radioactivity, and their potential to release radionuclides, metal(loid)s, radon gas, and milling reagents to the environment. The main objective of this study was to characterize the processes controlling the release, transport, and fate of U, radionuclides (Ra-226, Pb-210), and rare earth elements (REEs) downstream from two decommissioned tailings impoundments at the Bicroft Uranium Mine near Bancroft, Ontario. The Bicroft Mine operated from 1957 to 1963, and milled approximately 2,284,421 tonnes of U ore from granitic pegmatite dykes. This type of U deposit is relatively widespread throughout the Grenville Province in Ontario, Québec, and Labrador, and has recently been the focus of exploration as a source of REEs and other strategic metals. Samples of tailings, sediments, surface waters, and colloids were collected from the Bicroft Mine between 2010 and 2012. Regional-scale sampling of sediments and waters, as well as reanalysis of archived stream and lake sediments, were undertaken to determine natural background variation. The concentration of U in the Bicroft tailings samples varies from 3.1 to 210 mg/kg (median 19 mg/kg). Much higher concentrations were found in stream and pond sediments below the tailings impoundments (54 to 730 mg/kg; median 150 mg/kg). Uranium concentrations in regional lake sediments range from 0.4 to 140 mg/kg (median 4.2 mg/kg), and regional stream sediments range from 1.2 to 110 mg/kg (median 4.6 mg/kg). Seasonal sampling of tailings effluent shows that these waters are circumneutral (pH 6.6-8.3) and that the downstream concentrations of U and Ra-226 are generally highest in the fall. Comparison of filtered and unfiltered effluents, combined with synchrotron microanalyses of colloids, shows that the downstream mobility of REEs is limited by sorption to Fe- and Mn-(oxy)hydroxides. In contrast, U occurs mainly in the dissolved phase and its mobility does not appear to be limited by sorption to colloids or precipitation of secondary U phases. Geochemical modeling of the effluent demonstrates that the aqueous speciation of U is dominated by calcium-uranyl-carbonato complexes [e.g. Ca2UO2(CO3)3], which are known to diminish the sorption of U to mineral surfaces and suppress the reduction of U(VI) to less soluble U(IV). The results of this study provide improved understanding of the long-term stability of U tailings, and have implications for the design of environmental monitoring plans.
Summary(Plain Language Summary, not published)
Uranium mill tailings may pose a risk to ecosystems and human health because of their long-lived radioactivity, and their potential to release radionuclides, metal(loid)s, and radon to the environment. The main objective of this study was to characterize the release, transport, and fate of uranium, radionuclides, and rare earth elements (REEs) from two decommissioned tailings impoundments at the Bicroft Uranium Mine near Bancroft, Ontario. The results of this research show that uranium and REEs are naturally enriched in sediments in the Bancroft area, and the highest concentrations are found in mineralized, but unmined areas. At Bicroft, the mobility of REEs is limited by their association with suspended sediments, which settle-out of solution on the mine property. In contrast, uranium occurs mainly in dissolved form and is readily transported away from the tailings. Concentrations of uranium leaving the mine are relatively low, although they may exceed water quality guidelines in the fall.
GEOSCAN ID293623