Effects of Mineral Impurities and Heat on Uranium(VI) Sorption onto Bentonite (Final Report)

Tinnacher, Ruth M.; Bhattacharyya, Amrita; Huang, Patrick; Massey, Michael; Tournassat, Christophe; Fox, Patricia M.; Nico, Peter S.; Whittaker, Michael; Caporuscio, Florie; Rock, Marlena; Sauer, Kristen; Holmboe, Michael

doi:10.2172/1961544

Title: Effects of Mineral Impurities and Heat on Uranium(VI) Sorption onto Bentonite (Final Report)

Technical Report · Wed Mar 15 00:00:00 EDT 2023

DOI:https://doi.org/10.2172/1961544· OSTI ID:1961544

Tinnacher, Ruth M. ^[1]; Bhattacharyya, Amrita ^[2]; Huang, Patrick ^[1]; Massey, Michael ^[1]; Tournassat, Christophe ^[3]; Fox, Patricia M. ^[3]; Nico, Peter S. ^[3]; Whittaker, Michael ^[3]; Caporuscio, Florie ^[4]; Rock, Marlena ^[4]; Sauer, Kristen ^[4]; Holmboe, Michael ^[5]

California State Univ., East Bay, Hayward, CA (United States)
University of San Francisco, CA (United States); California State Univ., East Bay, Hayward, CA (United States)
Lawrence Berkeley National Lab. (LBNL), Berkeley, CA (United States)
Los Alamos National Lab. (LANL), Los Alamos, NM (United States)
Umea Univ. (Sweden)

Most nuclear waste disposal options include compacted bentonite, consisting of montmorillonite clay, as part of a barrier system to minimize contaminant mobility. Uranium (U) is the primary element in spent nuclear fuel, and from an environmental perspective, a potential contaminant of water resources. Furthermore, uranium may control nuclear fuel degradation rates and the consequent release of other radioactive contaminants based on its diffusive transport away from waste canisters. Uranium sorption onto clay and other mineral surfaces is expected to limit U(VI) mobility in these systems. However, at this point a prediction of U(VI) sorption and transport behavior in performance assessment (PA) models is complicated by a series of factors, such as: (1) the presence of various U(VI) solution species with different charges and sorption characteristics; (2) the complex microstructure of montmorillonite clay resulting in two types of clay porosities and multiple sorption sites; (3) the largely unknown effects of bentonite mineral impurities on pore water chemistry, U(VI) sorption and diffusion behavior; and (4) the potential impacts of heat, generated by the decay of spent fuel, on mineralogical and microstructural transformations, and any subsequent effects on radionuclide sorption and mobility. In this project, we investigated the effects of calcite impurities on U(VI) sorption and diffusion onto montmorillonite before and after mineral exposure to heat. Overall, our main goals were to: 1. Gain a mechanistic understanding of the effects of calcite impurities on U(VI) sorption and diffusion in montmorillonite/bentonite at variable chemical conditions, and before and after mineral exposure to heat; and to 2. Work towards the development of new surface complexation and diffusion models to predict U(VI) sorption and mobility in montmorillonite/bentonite while accounting for the impacts of calcite impurities and heat. In order to achieve these goals, we pursued the following research objectives and tasks: 1. Characterize the effects of calcite impurities on U(VI) sorption onto Na-montmorillonite, and evaluate if and how these effects change due to solids’ exposure to heat (Task 1). 2. Characterize U(VI) surface speciation in solid samples from Task 1, with a particular focus on U(VI) precipitates and co-precipitates (Task 2). 3. Test the relevance of observed changes in U(VI) sorption characteristics for U(VI) diffusive transport behavior in bentonite barriers (Task 3). 4. Evaluate the exclusion of anionic U(VI) solution complexes from clay nanopores (Task 4). 5. Building on Tasks 1-4, start the development of new surface complexation and reactive transport models that can simulate and predict U(VI) sorption and diffusion in complex bentonite systems (Task 5). A detailed description of all tasks, and their specific results and conclusions is provided in this report.

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Research Organization:: California State Univ., East Bay, Hayward, CA (United States)

Sponsoring Organization:: USDOE Office of Nuclear Energy (NE), Nuclear Energy University Program (NEUP)

DOE Contract Number:: NE0008683

OSTI ID:: 1961544

Report Number(s):: DOE-CSUEB-0008683; TRN: US2403577

Resource Relation:: Related Information: Zhang, C.; Liu, X.; Tinnacher, R. M.; Tournassat, C. Mechanistic Understanding of Uranyl Ion Complexation on Montmorillonite Edges: A Combined First-Principles Molecular Dynamics-Surface Complexation Modeling Approach. Environmental Science and Technology, 2018, 52, 8501-8509.Fox, P. M.; Tinnacher, R. M.; Cheshire, M. C.; Caporuscio, F.; Carrero, S.; Nico, P. S. Effects of Bentonite Heating on U(VI) Adsorption, Appl. Geochem., 2019, 109, 1-12.

Country of Publication:: United States

Language:: English

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