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281 results on '"Radionuclide transport"'

1. Hydromechanical characterization of gas transport amidst uncertainty for underground nuclear explosion detection

Author

Wenfeng Li, Chelsea W. Neil, J William Carey, Meng Meng, Luke P. Frash, and Philip H. Stauffer

Subjects
Underground nuclear explosion uncertainty quantification, Radionuclide transport, Biot effective stress coefficient, Fracture permeability, Matrix permeability, Engineering geology. Rock mechanics. Soil mechanics. Underground construction, TA703-712
Abstract

Given the challenge of definitively discriminating between chemical and nuclear explosions using seismic methods alone, surface detection of signature noble gas radioisotopes is considered a positive identification of underground nuclear explosions (UNEs). However, the migration of signature radionuclide gases between the nuclear cavity and surface is not well understood because complex processes are involved, including the generation of complex fracture networks, reactivation of natural fractures and faults, and thermo-hydro-mechanical-chemical (THMC) coupling of radionuclide gas transport in the subsurface. In this study, we provide an experimental investigation of hydro-mechanical (HM) coupling among gas flow, stress states, rock deformation, and rock damage using a unique multi-physics triaxial direct shear rock testing system. The testing system also features redundant gas pressure and flow rate measurements, well suited for parameter uncertainty quantification. Using porous tuff and tight granite samples that are relevant to historic UNE tests, we measured the Biot effective stress coefficient, rock matrix gas permeability, and fracture gas permeability at a range of pore pressure and stress conditions. The Biot effective stress coefficient varies from 0.69 to 1 for the tuff, whose porosity averages 35.3% ± 0.7%, while this coefficient varies from 0.51 to 0.78 for the tight granite (porosity

Published
2024
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2. Uncertainties and robustness with regard to the safety of a repository for high-level radioactive waste: introduction of a research initiative.

Author

Kurgyis, Kata, Achtziger-Zupančič, Peter, Bjorge, Merle, Boxberg, Marc S., Broggi, Matteo, Buchwald, Jörg, Ernst, Oliver G., Flügge, Judith, Ganopolski, Andrey, Graf, Thomas, Kortenbruck, Philipp, Kowalski, Julia, Kreye, Phillip, Kukla, Peter, Mayr, Sibylle, Miro, Shorash, Nagel, Thomas, Nowak, Wolfgang, Oladyshkin, Sergey, and Renz, Alexander

Subjects
RADIOACTIVE wastes, RADIOACTIVE waste repositories, RADIOACTIVE waste sites, RADIOACTIVE waste disposal, DATA management
Abstract

The Federal Company for Radioactive Waste Disposal (BGE mbH) is tasked with the selection of a site for a high-level radioactive waste repository in Germany in accordance with the Repository Site Selection Act. In September 2020, 90 areas with favorable geological conditions were identified as part of step 1 in phase 1 of the Site Selection Act. Representative preliminary safety analyses are to be carried out next to support decisions on the question, which siting regions should undergo surface-based exploration. These safety analyses are supported by numerical simulations building on geoscientific and technical data. The models that are taken into account are associated with various sources of uncertainties. Addressing these uncertainties and the robustness of the decisions pertaining to sites and design choices is a central component of the site selection process. In that context, important research objectives are associated with the question of how uncertainty should be treated through the various data collection, modeling and decision-making processes of the site selection procedure, and how the robustness of the repository system should be improved. BGE, therefore, established an interdisciplinary research cluster to identify open questions and to address the gaps in knowledge in six complementary research projects. In this paper, we introduce the overall purpose and the five thematic groups that constitute this research cluster. We discuss the specific questions addressed as well as the proposed methodologies in the context of the challenges of the site selection process in Germany. Finally, some conclusions are drawn on the potential benefits of a large method-centered research cluster in terms of simulation data management. [ABSTRACT FROM AUTHOR]

Published
2024
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3. Radionuclide Transport Simulations Supporting Proposed Borehole Waste Disposal in Israel.

Author

Swager, Katherine Carol, Bourret, Suzanne Michelle, Bussod, Gilles Y., Balaban, Noa, Boukhalfa, Hakim, Calvo, Ran, Klein-BenDavid, Ofra, Lucero, Dolan, Reznik, Itay J., Rosenzweig, Ravid, and Stauffer, Philip H.

Subjects
RADIOACTIVE wastes, RADIOACTIVE waste sites, WASTE management, RADIOACTIVE waste disposal, RADIOISOTOPES, WATER table, MULTIPHASE flow, URANIUM mining
Abstract

A scientific collaboration between the U.S. and Israel is underway to assess the suitability of a potential site for subsurface radioactive waste disposal in the Negev Desert, Israel. The Negev Desert has several favorable attributes for geologic disposal, including an arid climate, a deep vadose zone, interlayered low-permeability lithologies, and carbonate rocks with high uranium-sorption potential. These features may provide a robust natural barrier to radionuclide migration. Geologic and laboratory characterization data from the Negev Desert are incorporated into multiphase flow and transport models, solved using PFLOTRAN, to aid in site characterization and risk analysis that will support decision-making for waste disposal in an intermediate-depth borehole design. The lithology with the greatest uranium sorption potential at the site is phosphorite. We use modeling to evaluate the ability of this layer to impact uranium transport around a proposed disposal borehole. The current objective of the simulations is focused on characterizing hypothetical leakage from waste canisters and subsequent uranium migration under three infiltration scenarios. Here, we describe a hydrogeologic model based on data from a local exploratory borehole and present results for uranium flow and transport simulations under varying infiltration scenarios. We find that under the current climate conditions, it is likely that uranium will remain in the near-field of the borehole for thousands of years. However, under a hypothesized extreme climate scenario representing an increase in infiltration by a factor of 300x above present-day values, uranium may break through the phosphorite layer and exit the base of the model domain (~200 m above the water table) within 1000 years. Simulation results have direct implications for the planning of nuclear waste disposal in the Negev Desert, and specifically in intermediate-depth boreholes. [ABSTRACT FROM AUTHOR]

Published
2023
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4. Steady-state radiochemical transport model of the molten salt reactor experiment.

Author

Shahbazi, Shayan, Romano, Paul, Fei, Tingzhou, and Grabaskas, David

Subjects
*MOLTEN salt reactors, *RADIOACTIVE decay, *NUCLEAR fuels, *RADIOISOTOPES
Abstract

A radiochemical transport model of the Molten Salt Reactor Experiment (MSRE) was formulated based on the material derivative featuring system level 1-D flow providing spatial dependence accounting for multiple phenomena including radioactive decay, chemical removal, and fuel depletion across custom volume regions. The steady-state version, which is based on a system of ODE's, can be solved efficiently and is useful for sensitivity studies utilizing Monte Carlo sampling. Accounting for multiple phenomena in a fully coupled model is necessary to understand the complexities of transport and distribution of radionuclides throughout the primary loop of a flowing fuel reactor. [ABSTRACT FROM AUTHOR]

Published
2022
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6. The value of simplified models of radionuclide transport for the safety assessment of nuclear waste repositories: A benchmark study

Author

Selzer, Philipp, Shao, Haibing, Behrens, C., Lehmann, Christoph, Seydewitz, R., Lu, Renchao, Kreye, P., Rühaak, W., Kolditz, Olaf, Selzer, Philipp, Shao, Haibing, Behrens, C., Lehmann, Christoph, Seydewitz, R., Lu, Renchao, Kreye, P., Rühaak, W., and Kolditz, Olaf

Abstract

In order to assess sites for a deep geological repository for storing high-level nuclear waste safely in Germany, various numerical models and tools will be in use. For their interaction within one workflow, their reproducibility, and reliability version-controlled open-source solutions and careful documentation of model setups, results and verifications are of special value. However, spatially fully resolved models including all relevant physical and chemical processes are neither computationally feasible for large domains nor is the data typically available to parameterize such models. Thus, simplified models are crucial for the pre-assessment of possible sites to narrow down the list of suitable candidates for which detailed site investigations and fully resolved models will be done at a later stage. Still, the accuracy of these simplified models is of importance as the pre-assessment of suitable sites will be based on them. In this study, we compare the modelling capabilities of TransPyREnd, a one-dimensional transport code based on finite differences, specifically developed for the fast estimation of radionuclide transport by the German federal company for radioactive waste disposal (BGE), with OpenGeoSys, which is a modelling platform based on finite elements in up to three spatial dimensions. Both codes are used in the site selection procedure for the German nuclear waste repository. The comparison of the model results of TransPyREnd and OpenGeoSys is augmented by comparisons with an analytical solution for a homogeneous material. For the purpose of numerical benchmarking, we consider a geological profile located in southern Germany as an example where the hypothetical repository is located in a clay-stone formation. TransPyREnd and OpenGeoSys yield overall similar results. However, both codes use different discretizations which impact is the highest for strongly sorbing compounds, while the difference gets negligible for less sorbing and more diffusive compo

Published
2024

7. Radionuclide Transport Simulations Supporting Proposed Borehole Waste Disposal in Israel

Author

Katherine Carol Swager, Suzanne Michelle Bourret, Gilles Y. Bussod, Noa Balaban, Hakim Boukhalfa, Ran Calvo, Ofra Klein-BenDavid, Dolan Lucero, Itay J. Reznik, Ravid Rosenzweig, and Philip H. Stauffer

Subjects
intermediate borehole disposal, radionuclide transport, multiphase flow, PFLOTRAN, Geology, QE1-996.5
Abstract

A scientific collaboration between the U.S. and Israel is underway to assess the suitability of a potential site for subsurface radioactive waste disposal in the Negev Desert, Israel. The Negev Desert has several favorable attributes for geologic disposal, including an arid climate, a deep vadose zone, interlayered low-permeability lithologies, and carbonate rocks with high uranium-sorption potential. These features may provide a robust natural barrier to radionuclide migration. Geologic and laboratory characterization data from the Negev Desert are incorporated into multiphase flow and transport models, solved using PFLOTRAN, to aid in site characterization and risk analysis that will support decision-making for waste disposal in an intermediate-depth borehole design. The lithology with the greatest uranium sorption potential at the site is phosphorite. We use modeling to evaluate the ability of this layer to impact uranium transport around a proposed disposal borehole. The current objective of the simulations is focused on characterizing hypothetical leakage from waste canisters and subsequent uranium migration under three infiltration scenarios. Here, we describe a hydrogeologic model based on data from a local exploratory borehole and present results for uranium flow and transport simulations under varying infiltration scenarios. We find that under the current climate conditions, it is likely that uranium will remain in the near-field of the borehole for thousands of years. However, under a hypothesized extreme climate scenario representing an increase in infiltration by a factor of 300x above present-day values, uranium may break through the phosphorite layer and exit the base of the model domain (~200 m above the water table) within 1000 years. Simulation results have direct implications for the planning of nuclear waste disposal in the Negev Desert, and specifically in intermediate-depth boreholes.

Published
2023
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8. Simulation of Iodine Spiking phenomenon during Design Extended Condition type A conditions at VVER-1000 and Generic PWR.

Author

Zimmerl, Raphael, Giannotti, Walter, and Muellner, Nikolaus

Subjects
*PRESSURIZED water reactors, *NUCLEAR reactors, *IODINE, *RELIEF valves, *FISSION products, *NUCLEAR reactor cores, *SYSTEM failures
Abstract

After the Fukushima Daichi accident in 2011 design extension conditions (DEC) came into focus. Most regulatory regimes now require that design extension conditions are considered in the design of new reactors, while existing reactors should try back fitting safety enhancements to be able to deal with design extension conditions as far as reasonably achievable. DEC are divided in categories A and B, where DEC-A scenarios are characterized by multiple failures of safety systems but with the reactor core remaining intact. A phenomenon that plays a significant role in DEC-A scenarios involving a containment bypass is Iodine Spiking (IS). In this paper we analyse a PRImary to SEcondary leaking accident (PRISE) with the assumption of a stuck open atmospheric relief valve at the first opening at two different reactor designs (VVER-1000, Generic PWR). For the thermal hydraulic best estimate simulation we use RELAP5-3D, for the transport of iodine we use the Relap5-3D radionuclide transport model. Additionally, to analyse the Iodine Spiking (IS) phenomenon for the examined accident scenario, we created an empirical IS model which is based on the existing NRC IS model to estimate how much iodine is released to the primary system from the fuel. The results of this study show that the Relap5-3D radionuclide transport model is capable of providing a bounding analysis on the iodine released to the environment. The analysis also shows that good results can be achieved for the analysed scenarios using an empirical model to estimate the iodine released to the primary system. The analysis also shows that during said scenario significant quantities of radioactive fission products are released into the environment. [ABSTRACT FROM AUTHOR]

Published
2024
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10. The value of simplified models of radionuclide transport for the safety assessment of nuclear waste repositories: A benchmark study.

Author

Selzer P, Shao H, Behrens C, Lehmann C, Seydewitz R, Lu R, Kreye P, Rühaak W, and Kolditz O

Abstract

In order to assess sites for a deep geological repository for storing high-level nuclear waste safely in Germany, various numerical models and tools will be in use. For their interaction within one workflow, their reproducibility, and reliability version-controlled open-source solutions and careful documentation of model setups, results and verifications are of special value. However, spatially fully resolved models including all relevant physical and chemical processes are neither computationally feasible for large domains nor is the data typically available to parameterize such models. Thus, simplified models are crucial for the pre-assessment of possible sites to narrow down the list of suitable candidates for which detailed site investigations and fully resolved models will be done at a later stage. Still, the accuracy of these simplified models is of importance as the pre-assessment of suitable sites will be based on them. In this study, we compare the modelling capabilities of TransPyREnd, a one-dimensional transport code based on finite differences, specifically developed for the fast estimation of radionuclide transport by the German federal company for radioactive waste disposal (BGE), with OpenGeoSys, which is a modelling platform based on finite elements in up to three spatial dimensions. Both codes are used in the site selection procedure for the German nuclear waste repository. The comparison of the model results of TransPyREnd and OpenGeoSys is augmented by comparisons with an analytical solution for a homogeneous material. For the purpose of numerical benchmarking, we consider a geological profile located in southern Germany as an example where the hypothetical repository is located in a clay-stone formation. TransPyREnd and OpenGeoSys yield overall similar results. However, both codes use different discretizations which impact is the highest for strongly sorbing compounds, while the difference gets negligible for less sorbing and more diffusive compounds as higher diffusion tends to blur the initial conditions. Overall, the OpenGeoSys model is more exact whereas the TransPyREnd model has considerable faster run times. We found in our example, that significant substance amounts are only leaving the host rock formation, if apparent diffusion is high, for which case both codes give similar results, while relative differences are considerable for strongly sorbing compounds. However, in the latter case no significant substance amount of radionuclides leaves the host-rock formation, thus deeming the differences in the model results minor for the overall safety assessments of sites., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024. Published by Elsevier B.V.)

Published
2024
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11. An Adjoint Sensitivity Model for Radionuclide Transport in Heterogeneous Discrete Fractured Porous Formation in Steady‐State Regime.

Author

Hayek, Mohamed, RamaRao, Banda S., and Lavenue, Marsh

Subjects
TRANSPORT equation, RADIOISOTOPES, PARTIAL differential equations, MATRIX inversion, UNDERGROUND storage, POROUS materials
Abstract

The development of the adjoint state method for the system of partial differential equations (PDEs) describing radionuclide transport in heterogeneous discrete fractured porous media in steady‐state regime is presented in this study for both continuous and discrete adjoint approaches. The continuous adjoint approach has its own advantage in the sense that the adjoint system can be derived in terms of PDEs which can be solved analytically for specific performance measures. These PDEs can then be used to obtain a physical interpretation of the adjoint state functions. The discrete adjoint approach permits a simpler mathematical treatment based on the use of the same matrix (or its transpose) of the linear system of the discretized transport equations referring to from hereon as the forward problem. Analytical solutions for both the forward problem and its associated adjoint problem have been derived for radionuclide transport in layered formations including a fracture using an analytical inversion of tridiagonal matrices. A set of 14 formulas of sensitivity coefficients with respect to pertinent system parameters has been derived and presented in integral forms. Analytical results have been compared with numerical results and have shown excellent agreements. The discrete adjoint approach has been coupled with the differential sensitivity analysis method and applied to a real field case involving the performance assessment of a site currently being considered for underground nuclear storage in northern Switzerland, Zürich Nordost. The results show that when a fracture is present in the vicinity of waste repository, the state parameter controlling flow through the fracture, referred to herein as fracture transmissivity, is among the important parameters which should be considered in sensitivity analysis studies. Key Points: A full mathematical/numerical adjoint sensitivity model for steady‐state RN transport in heterogeneous discrete fractured media is presentedAnalytical solutions for concentrations and adjoint states have been derived for the case of layered formations including a fractureThe developed adjoint approach has been coupled with the differential sensitivity analysis method and applied to a real field case [ABSTRACT FROM AUTHOR]

Published
2021
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13. Coupled hydro-thermal flow and radionuclide transport driven by spatial variation of heat-generating radioactive wastes in shale formations.

Author

Chang, Kyung Won and LaForce, Tara

Subjects
*RADIOACTIVE wastes, *RADIOACTIVE waste disposal, *RADIOISOTOPES, *SPATIAL variation, *PACKAGING waste, *HEAT pulses, *SHALE
Abstract

Deep geologic disposal of multiple nuclear waste packages with various heat sources can induce nonuniform hydro-thermal behaviors in the near-field of the repository, consequently influencing the long-term radionuclide transport in the far-field once waste form breach initiates. This study looks into three cases with variation in the spatial order of six groups of heat sources (10th, 50th, 75th, 90th, 95th, and 99th percentiles of heat outputs generated from 1,981 as-loaded dual-purpose canisters in the field site) in a shale-hosted repository with respect to the uni-directional groundwater flow (from west to east): (1) cooler waste packages from west to east, (2) hotter waste packages from west to east, and (3) hottest waste packages in the middle of the repository. Our field-scale PFLOTRAN simulation represents heat-driven multiphysics coupled mechanisms, including multiphase flow, heat transfer, and chemical/radioactive transport, and also, calculates the onset of waste form breach based on temperature-dependent canister vitality. The results from this sensitivity study will quantify the short- (less than 1 × 10 3 years) and long-term (up to 1 × 10 6 years) impacts of sporadic heat pulses from waste package on the spatio-temporal perturbation in hydro-thermal flow quantities and the rate of radionuclide transport in both near- and far-field of the repository system. • Non-uniform heat energy from radioactive wastes causes near- and far-field dynamics. • Intense pressurization occurs near greater heat sources by longer presence of gas. • Location of heat sources regarding groundwater flow impact radionuclide transport. • Reactive characteristics of radioactive isotopes control long-term radionuclide transport. [ABSTRACT FROM AUTHOR]

Published
2024
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14. 1-D modeling of radionuclide transport via heterogeneous geological formations for arbitrary length decay chains using numerical inversion of Laplace transforms

Author

van den Akker, Bret Patrick and Ahn, Joonhong

Subjects
Radionuclide transport, Talbot's method, Laplace inversion, TTBX, Other Physical Sciences, Interdisciplinary Engineering, Energy
Abstract

We present the Laplace-transformed analytical solution (LTAS) to the one-dimensional radionuclide transport equation for an arbitrary length decay-chain through an arbitrary combination of multiply fractured and porous transport segments subject to an arbitrary time-dependent release mode at the entrance point to the series of transport segments. The LTAS may be numerically inverted to obtain the time-dependent concentration of the radionuclides of interest at an arbitrary down gradient location. For a special case, where the source function is defined as the band release with a single radionuclide without precursors, the Laplace inverse transformation could be performed analytically, yielding a closed-form analytical solution. A computer code, TTBX, has been developed by implementing the LTAS, and benchmarked against the closed-form analytical solution. Numerical examples are presented to demonstrate the utility of these solutions and the importance of increased fidelity in the transport pathway for reliable performance assessment for the geological disposal of spent nuclear fuels. © 2013 Elsevier Ltd. All rights reserved.

Published
2014

15. 1-D modeling of radionuclide transport via heterogeneous geological formations for arbitrary length decay chains using numerical inversion of Laplace transforms

Author

Van Den Akker, BP and Ahn, J

Subjects
Radionuclide transport, Talbot's method, Laplace inversion, TTBX, Energy, Interdisciplinary Engineering, Other Physical Sciences
Abstract

We present the Laplace-transformed analytical solution (LTAS) to the one-dimensional radionuclide transport equation for an arbitrary length decay-chain through an arbitrary combination of multiply fractured and porous transport segments subject to an arbitrary time-dependent release mode at the entrance point to the series of transport segments. The LTAS may be numerically inverted to obtain the time-dependent concentration of the radionuclides of interest at an arbitrary down gradient location. For a special case, where the source function is defined as the band release with a single radionuclide without precursors, the Laplace inverse transformation could be performed analytically, yielding a closed-form analytical solution. A computer code, TTBX, has been developed by implementing the LTAS, and benchmarked against the closed-form analytical solution. Numerical examples are presented to demonstrate the utility of these solutions and the importance of increased fidelity in the transport pathway for reliable performance assessment for the geological disposal of spent nuclear fuels. © 2013 Elsevier Ltd. All rights reserved.

Published
2014

16. Recovering the Effects of Subgrid Heterogeneity in Simulations of Radionuclide Transport Through Fractured Media

Author

Thomas Williams, Jordi Sanglas, Paolo Trinchero, Guanqun Gai, Scott L. Painter, and Jan-Olof Selroos

Subjects
groundwater modeling, radionuclide transport, discrete fracture network, upscaling, downscaling, Science
Abstract

Groundwater flow and contaminant transport through fractured media can be simulated using Discrete Fracture Network (DFN) models which provide a natural description of structural heterogeneity. However, this approach is computationally expensive, with the large number of intersecting fractures necessitated by many real-world applications requiring modeling simplifications to be made for calculations to be tractable. Upscaling methods commonly used for this purpose can result in some loss of local-scale variability in the groundwater flow velocity field, resulting in underestimation of particle travel times, transport resistance and retention in transport calculations. In this paper, a transport downscaling algorithm to recover the transport effects of heterogeneity is tested on a synthetic Brittle Fault Zone model, motivated by the problem of large safety assessment calculations for geological repositories of spent nuclear fuel. We show that the variability in the local-scale velocity field which is lost by upscaling can be recovered by sampling from a library of DFN transport paths, accurately reproducing DFN transport statistic distributions and radionuclide breakthrough curves in an upscaled model.

Published
2021
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17. Aging effects on Cesium-137 (137Cs) sorption and transport in association with clay colloids.

Author

Telfeyan, Katherine, Reimus, Paul W., Boukhalfa, Hakim, and Ware, S. Doug

Subjects
*COLLOIDS, *CLAY, *CESIUM isotopes, *SORPTION, *RADIOISOTOPES
Abstract

Migration of radionuclides via colloid-facilitated transport is an important component of nuclear repository performance models. 137Cs sorption to bentonite colloids follows multi-site behavior, with sorption to weak sites being a rapid process and sorption to strong sites having slow kinetics. Experiments in this study targeted desorption of 137Cs from strong sites on the colloids by placing the 137Cs-bearing colloids in contact with a strongly-sorbing zeolite material that competes with the colloids for 137Cs sorption. Batch and column experiments were conducted to examine the effects of aging (i.e., increased contact time between 137Cs and colloids) on colloid-facilitated transport of 137Cs through crushed analcime columns. A larger proportion of 137Cs-bearing colloids eluted through a series of columns when the colloids were aged for 1200 days prior to injection in comparison to unaged colloids. Aging the colloids increased the partitioning of 137Cs to the colloids by nearly 20% after 1200 h. Slow desorption (0.27 hr−1) from the strong sites resulted in an increase of the Cs fraction bound to the strong sites from 0.365 to 0.87 by the second column injection, resulting in increased colloid-facilitated transport of Cs through strongly-sorbing zeolites from 0 in the second unaged column to 10% in the second aged column. [ABSTRACT FROM AUTHOR]

Published
2020
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19. Radionuclide Transport Simulations Supporting Proposed Borehole Waste Disposal in Israel

Author

Stauffer, Katherine Carol Swager, Suzanne Michelle Bourret, Gilles Y. Bussod, Noa Balaban, Hakim Boukhalfa, Ran Calvo, Ofra Klein-BenDavid, Dolan Lucero, Itay J. Reznik, Ravid Rosenzweig, and Philip H.

Subjects
intermediate borehole disposal, radionuclide transport, multiphase flow, PFLOTRAN
Abstract

A scientific collaboration between the U.S. and Israel is underway to assess the suitability of a potential site for subsurface radioactive waste disposal in the Negev Desert, Israel. The Negev Desert has several favorable attributes for geologic disposal, including an arid climate, a deep vadose zone, interlayered low-permeability lithologies, and carbonate rocks with high uranium-sorption potential. These features may provide a robust natural barrier to radionuclide migration. Geologic and laboratory characterization data from the Negev Desert are incorporated into multiphase flow and transport models, solved using PFLOTRAN, to aid in site characterization and risk analysis that will support decision-making for waste disposal in an intermediate-depth borehole design. The lithology with the greatest uranium sorption potential at the site is phosphorite. We use modeling to evaluate the ability of this layer to impact uranium transport around a proposed disposal borehole. The current objective of the simulations is focused on characterizing hypothetical leakage from waste canisters and subsequent uranium migration under three infiltration scenarios. Here, we describe a hydrogeologic model based on data from a local exploratory borehole and present results for uranium flow and transport simulations under varying infiltration scenarios. We find that under the current climate conditions, it is likely that uranium will remain in the near-field of the borehole for thousands of years. However, under a hypothesized extreme climate scenario representing an increase in infiltration by a factor of 300x above present-day values, uranium may break through the phosphorite layer and exit the base of the model domain (~200 m above the water table) within 1000 years. Simulation results have direct implications for the planning of nuclear waste disposal in the Negev Desert, and specifically in intermediate-depth boreholes.

Published
2023
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20. Mountain-scale transport of radioactive solutes and colloids through the unsaturated zone of Yucca Mountain, Nevada

Author

Moridis, George J. and Yongkoo, Seol

Subjects
Radionuclide Transport
Abstract

The U.S. Department of Energy is actively investigating the technical feasibility of permanent disposal of high-level nuclear waste in a repository to be situated in the unsaturated zone (UZ) at Yucca Mountain (YM), Nevada. The objectives of this study are to evaluate the transport of radioactive solutes and colloids under ambient conditions from the potential repository horizon to the water table and to determine processes and geohydrologic features that significantly affect radionuclide transport. The radionuclide transport model considers the site hydrology and the effects of the spatial distribution of hydraulic and transport properties in the fractured rock units of the YM subsurface. Several radionuclides (solutes and colloids) with varying properties are investigated. The results of the study indicate that the most important factors affecting radionuclide transport are the subsurface geology and site hydrology, i.e., the presence of faults (they dominate and control transport), fractures (the main migration pathways), and the relative distribution of zeolitic and vitric tuffs. Radioactive decay, diffusion from the fractures into the matrix, and subsequent sorption (for solutes) or filtration (for colloids) onto, are the main retardation processes. For solutes, arrival times at the watertable increase with the sorption distribution coefficients of the various species, and may have to account for contributions from the decay daughters of certain radionuclides. Changes in future climatic conditions can have a significant effect on transport, as increasing infiltration leads to faster transport to the water table. The transport of colloids is strongly influenced by their size (as it affects diffusion into the matrix, straining at hydrogeologic unit interfaces, and transport velocity) and by the fracture attributes.

Published
2003

25. Potential for biocolloid transport of cesium at high ionic strength.

Author

Zengotita, F.E., Emerson, H.P., Stanley, F.E., Dittrich, T.M., Richmann, M.K., Reed, D., and Swanson, J.

Subjects
*CESIUM, *CARBONATE minerals, *IONIC strength, *SOLUTION (Chemistry), *BACTERIAL population, *PILOT plants, *DOLOMITE
Abstract

In subsurface repositories, active bacterial populations may directly influence the fate and transport of radionuclides including in salt repository systems like the Waste Isolation Pilot Plant in Carlsbad, NM. This research quantified the potential for transport and interaction between Chromohalobacter sp. and Cs in a high ionic strength system (2.6 M NaCl) containing natural minerals. Mini-column experiments showed that Chromohalobacter moved nearly un-retarded under these conditions and that there was neither association of Cs with microbes nor dolomite despite changes in bacterial metabolic phases. Growth batch experiments that monitored the potential uptake of Cs into the microbes confirmed results in column experiments where intracellular uptake of Cs by Chromohalobacter was not observed. These results show that Cs may be highly mobile if released in high ionic strength systems and/or carbonate minerals with negligible inhibition by these microbes. • No Chromohalobacter interaction with cesium at high salt. • No adsorption and intracellular uptake of cesium with Chromohalobacter. • Interaction of cesium with dolomite at high ionic strength. [ABSTRACT FROM AUTHOR]

Published
2019
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26. Spatial modelling of Cs-137 and Sr-90 fallout after the Fukushima Nuclear Power Plant accident.

Author

Bilici, Sevim, Külahcı, Fatih, and Bilici, Ahmet

Subjects
*CESIUM isotopes, *RADIOACTIVE fallout, *LAKES, *GEOGRAPHIC spatial analysis, *SEDIMENT sampling, *NUCLEAR power plants
Abstract

Determination of radionuclides transport characteristics is among the most significant research topics, which require extensive multidisciplinary works. The spatial modeling methods are suggested to determine the effects of radioactive fallout. The spatial analysis has a history of approximately 250 years based on micro-scales, but today it has extended to macroscopic systems. After Fukushima accident, radioactive fallout in water and bottom sediment samples are collected from the deepest tectonic freshwater lake in Turkey, Hazar Lake, and Point Cumulative SemiVariogram and Triple Diagram models are employed for depiction their features. [ABSTRACT FROM AUTHOR]

Published
2019
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27. An Adjoint Sensitivity Model for Steady‐State Sequentially Coupled Radionuclide Transport in Porous Media.

Author

Hayek, Mohamed, RamaRao, Banda S., and Lavenue, Marsh

Subjects
POROUS materials, ADJOINT differential equations, RADIOISOTOPES, PARTIAL differential equations, FINITE differences
Abstract

This work presents an efficient mathematical/numerical model to compute the sensitivity coefficients of a predefined performance measure to model parameters for one‐dimensional steady‐state sequentially coupled radionuclide transport in a finite heterogeneous porous medium. The model is based on the adjoint sensitivity approach that offers an elegant and computationally efficient alternative way to compute the sensitivity coefficients. The transport parameters include the radionuclide retardation factors due to sorption, the Darcy velocity, and the effective diffusion/dispersion coefficients. Both continuous and discrete adjoint approaches are considered. The partial differential equations associated with the adjoint system are derived based on the adjoint state theory for coupled problems. Physical interpretations of the adjoint states are given in analogy to results obtained in the theory of groundwater flow. For the homogeneous case, analytical solutions for primary and adjoint systems are derived and presented in closed forms. Numerically calculated solutions are compared to the analytical results and show excellent agreements. Insights from sensitivity analysis are discussed to get a better understanding of the values of sensitivity coefficients. The sensitivity coefficients are also computed numerically by finite differences. The numerical sensitivity coefficients successfully reproduce the analytically derived sensitivities based on adjoint states. A derivative‐based global sensitivity method coupled with the adjoint state method is presented and applied to a real field case represented by a site currently being considered for underground nuclear storage in Northern Switzerland, "Zürich Nordost", to demonstrate the proposed method. The results show the advantage of the adjoint state method compared to other methods in term of computational effort. Key Points: A full mathematical/numerical adjoint sensitivity approach for steady‐state sequentially coupled radionuclide transport in heterogeneous media is presentedAnalytical expressions including adjoint state functions and sensitivity coefficients are derived in closed forms for the homogeneous caseA derivative‐based global sensitivity method coupled with the adjoint approach is presented and applied to a real field case [ABSTRACT FROM AUTHOR]

Published
2019
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28. Tellurium behaviour in the Fukushima Dai-ichi Nuclear Power Plant accident.

Author

Dickson, Raymond S. and Glowa, Glenn A.

Subjects
*NUCLEAR power plants, *TELLURIUM, *CHEMICAL species, *FUKUSHIMA Nuclear Accident, Fukushima, Japan, 2011
Abstract

The behaviour of tellurium radionuclides in the Fukushima Dai-ichi Nuclear Power Plant accident was examined to determine if it is consistent with the current understanding of tellurium chemistry, and whether there is any evidence of tellurium dispersal by species other than aerosols (e.g., vapours). Previous speciation studies, hot-cell experiments, in-reactor experiments and the transport from the Chernobyl reactor accident indicated that tellurium would behave primarily as a particulate species that condensed at high temperature, although the initial chemical species may have transformed to other solid species on cooling and reaction with environmental compounds (e.g., air). The main volatile tellurium species expected would be organic tellurides, which could be produced by radiolytic or biochemical routes, and have reasonable stability under environmental conditions. The behaviour of 137Cs, which behaves exclusively as a particulate species in air at environmental temperatures, was compared with that of tellurium. The behaviour of tellurium was found to be consistent with the current understanding and no evidence of significant tellurium transport by vapour species was found. • Tellurium release and transport data from Fukushima Dai-ichi were reviewed. • Tellurium behaved as particulate species only, with no evidence of vapour transport. • Particulate behaviour is consistent with present experimental understanding of Te. [ABSTRACT FROM AUTHOR]

Published
2019
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29. Modelling Environmental Impacts of Cesium-137 Under a Hypothetical Release of Radioactive Waste.

Author

Lin, Yan, Couture, Raoul-Marie, Klein, Heiko, Ytre-Eide, Martin Album, Dyve, Jan Erik, Lind, Ole Christian, Bartnicki, Jerzy, Nizzetto, Luca, Butterfield, Daniel, Larssen, Thorjørn, and Salbu, Brit

Subjects
CESIUM isotopes, RADIOACTIVE wastes, ATMOSPHERIC transport, STORAGE tanks, NUCLEAR facilities, CAUSATION (Philosophy)
Abstract

Waste tanks at the nuclear facility located at Sellafield, UK, represent a nuclear source which could release radionuclides to the atmosphere. A model chain which combines atmospheric transport, deposition as well as riverine transport to sea has been developed to predict the riverine activity concentrations of 137Cs. The source term was estimated to be 9 × 104 TBq of 137Cs, or 1% of the assumed total 137Cs inventory of the HAL (Highly Active Liquid) storage tanks. Air dispersion modelling predicted 137Cs deposition reaching 127 kBq m−2 at the Vikedal catchment in Western Norway. Thus, the riverine transport model predicted that the activity concentration of 137Cs in water at the river outlet could reach 9000 Bq m−3 in the aqueous phase and 1000 Bq kg−1 in solid phase at peak level. The lake and river reaches showed different transport patterns due to the buffering effects caused by dilution and slowing down of water velocity. [ABSTRACT FROM AUTHOR]

Published
2019
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30. Assessment of the potential for criticality in the far field of a used nuclear fuel repository.

Author

Atz, Milos, Salazar, Alex, Hirano, Fumio, Fratoni, Massimiliano, and Ahn, Joonhong

Subjects
*NUCLEAR fuels, *LIGHT water reactors, *NUCLEAR fuel rods, *LATTICE field theory, *DISSOLUTION (Chemistry)
Abstract

Abstract This study aims to assess the likelihood for criticality in the far field of a repository for direct disposal of commercial light water reactor used nuclear fuel. Two models are used in combination: (1) a neutronics model to estimate the minimum critical masses of spherical, water-saturated depositions of fissile material; (2) a transport model to simulate the dissolution of waste packages arranged in an array and the subsequent transport of fissile solutes through fractured bedrock to a single accumulation location. The neutronics model shows that heavy metals from different types of used fuel present the same minimum critical mass behavior in the parameter space of initial enrichment and burnup, dictated largely by the fissile content. However, the magnitude of the minimum critical mass varies significantly within that parameter space, and secondary effects like the presence of absorbing nuclides play a minor role. The transport model employs various subsurface transport scenarios, and for each scenario the mass of each isotope and the overall fissile content of the accumulation is reported from the time of canister failure up to one hundred million years at various distances from the repository edge. Taking the results of the two models in concert, it is shown that even if the accumulation of a critical mass is possible under conservative conditions, these conditions are unlikely to be present in the vicinity of a carefully engineered repository. Based on the results of each model, recommendations for risk mitigation in terms of waste characteristics and repository design are given. [ABSTRACT FROM AUTHOR]

Published
2019
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31. Investigation of 3H, 99Tc, and 90Sr transport in fractured rock and the effects of fracture-filling/coating material at LILW disposal facility.

Author

Kim, Won-Seok, Han, Sangsoo, Ahn, Jinmo, and Um, Wooyong

Subjects
STRONTIUM, MATERIALS, ROCKS
Abstract

Batch adsorption, batch diffusion, and flow-through column experiments were conducted using groundwater and fractured rock collected in unsaturated zone to increase our understanding of sorption and transport behavior of radionuclides. Increasing Kd values were observed in the sequence 90Sr, 99Tc, and 3H regardless of the geological media tested. For all sorbing radionuclides, Kd values for the fracture-filling/coating material were observed to be higher than those for without fracture-filling/coating material regardless of the groundwater. These higher Kd values are the result of zeolite mineral in filling/coating material of fractured rock. The batch diffusion and flow-through column experiments were also conducted using the same fractured rock sample, and the results of diffusion and column experiments showed similar trend of radionuclide sorption and transport to sorption experiment. In this study, sorption Kd of radionuclide was determined and used to increase our understanding of radionuclide retardation through fracture-filling/coating materials. [ABSTRACT FROM AUTHOR]

Published
2019
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37. Simulation of radioactive plume transport in the atmosphere including dynamics of particle aggregation and breakup.

Author

Wiechert, Alexander I., Ladshaw, Austin P., Kim, Yong-ha, Tsouris, Costas, and Yiacoumi, Sotira

Subjects
*RADIOACTIVE aerosols, *PARTICLE size distribution, *PARTICLE dynamics, *ATMOSPHERIC transport, *FRACTAL dimensions, *ATMOSPHERE, *FREE convection
Abstract

Accurate prediction of the atmospheric transport of debris particles relies heavily on our knowledge of the size distribution of the particles within a debris cloud. Assuming a fixed particle size during simulations is not always viable since the size distribution of the debris can change during transport. Various microphysical processes, such as aggregation and breakup, influence debris particles and dictate any changes to the size distribution. To track those changes that can occur, a population balance model can be adopted and instituted within a model framework. Nonetheless, many of the models that simulate the transport of radioactive debris following a device-driven fission incident have historically neglected to consider these processes. As such, this work describes our effort to develop a modeling framework capable of simulating the transport and deposition of a radioactive plume generated from a fission incident with a dynamic population balance including particle aggregation and breakup. The impact of aggregation and breakup, individually and collectively, on the particle size distribution is explored using the developed framework. When simulating aggregation, for example, six mechanisms, including Brownian coagulation, the convective enhancement to Brownian coagulation, van der Waals-viscous force correction for Brownian coagulation, gravitational collection, turbulent inertial motion, and turbulent shear, are considered. Brownian coagulation and its corrections have, as one would expect, a large impact on relatively small aggregates. Aggregates with a diameter that is less than or equal to 1.0 μm, for instance, comprise 50.6 vol % of all aggregates in the absence of aggregation and 31.2 vol % when Brownian coagulation and its corrections are considered. Gravitational collection and, to a much lesser extent, turbulent shear and turbulent inertial motion are, conversely, of great importance to relatively large aggregates (i.e., diameter greater than 3.0 μm). Additionally, the individual effects of atmospheric and particle parameters, such as wind speed and particle density, are examined. Of the parameters examined, turbulent energy dissipation and aggregate fractal dimension (i.e., aggregate shape with lower values representing more irregular particles) were of substantial importance since both terms directly impact aggregate stability and, by extension, the breakup rate. Large-scale transport and deposition simulations in a dry atmosphere are also presented and discussed as a proof of concept. • Dispersion model for radioactive aerosols in a dry atmosphere was developed. • Microphysical effects were considered through aerosol population balance modeling. • Aerosol size distribution quickly responded to changes in the simulated atmosphere. • Parameters influencing particle stability had the greatest impact on size distribution. • Radioactive debris transport was simulated at a scale of hundreds of kilometers. [ABSTRACT FROM AUTHOR]

Published
2023
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38. Predictive Modeling of a Simple Field Matrix Diffusion Experiment Addressing Radionuclide Transport in Fractured Rock. Is It So Straightforward?

Author

Soler, J. M., Neretnieks, Ivars, Moreno, Luis, Liu, Longcheng, Meng, Shuo, Svensson, U., Iraola, A., Ebrahimi, H., Trinchero, P., Molinero, J., Vidstrand, P., Deissmann, G., Říha, J., Hokr, M., Vetešník, A., Vopálka, D., Gvoždík, L., Polák, M., Trpkošová, D., Havlová, V., Park, D. -K, Ji, S. -H, Tachi, Y., Ito, T., Gylling, B., Lanyon, G. W., Soler, J. M., Neretnieks, Ivars, Moreno, Luis, Liu, Longcheng, Meng, Shuo, Svensson, U., Iraola, A., Ebrahimi, H., Trinchero, P., Molinero, J., Vidstrand, P., Deissmann, G., Říha, J., Hokr, M., Vetešník, A., Vopálka, D., Gvoždík, L., Polák, M., Trpkošová, D., Havlová, V., Park, D. -K, Ji, S. -H, Tachi, Y., Ito, T., Gylling, B., and Lanyon, G. W.

Abstract

The SKB GroundWater Flow and Transport of Solutes Task Force is an international forum in the area of conceptual and numerical modeling of groundwater flow and solute transport in fractured rocks relevant for the deep geological disposal of radioactive waste. Two in situ matrix diffusion experiments in crystalline rock (gneiss) were performed at POSIVA’s ONKALO underground facility in Finland. Synthetic groundwater containing several conservative and sorbing radiotracers was injected at one end of a borehole interval and flowed along a thin annulus toward the opposite end. Several teams performed predictive modeling of the tracer breakthrough curves using “conventional” modeling approaches (constant diffusion and sorption in the rock, no or minimum rock heterogeneity). Supporting information, derived from small-scale laboratory experiments, was provided. The teams were free to implement different concepts, use different codes, and apply the transport and retention parameters that they considered to be most suited (i.e., not a benchmark exercise). The main goal was the comparison of the different sets of results and the analysis of the possible differences for this relatively simple experimental setup with a well-defined geometry. Even though the experiment was designed to study matrix diffusion, the calculated peaks of the breakthrough curves were very sensitive to the assumed magnitude of dispersion in the borehole annulus. However, given the very different timescales for advection and matrix diffusion, the tails of the curves provided information concerning diffusion and retention in the rock matrix regardless of the magnitude of dispersion. In addition, although the task was designed to be a blind modeling exercise, the model results have also been compared to the measured experimental breakthroughs. Experimental results tend to show relatively small activities, wide breakthroughs, and early first arrivals, which are somewhat similar to model results using large, QC 20220608

Published
2022
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39. Endocytosis is a significant contributor to uranium(VI) uptake in tobacco (Nicotiana tabacum) BY-2 cells in phosphate-deficient culture

Author

(0000-0003-2150-8711) John, W., Lückel, B., (0000-0001-5038-0273) Matschiavelli, N., (0000-0002-5200-6928) Hübner, R., Matschi, S., Hoehenwarter, W., (0000-0001-9097-9299) Sachs, S., (0000-0003-2150-8711) John, W., Lückel, B., (0000-0001-5038-0273) Matschiavelli, N., (0000-0002-5200-6928) Hübner, R., Matschi, S., Hoehenwarter, W., and (0000-0001-9097-9299) Sachs, S.

Abstract

Endocytosis of metals in plants is a growing field of study involving metal uptake from the rhizosphere. Uranium, which is naturally and artificially released into the rhizosphere, is known to be taken up by certain species of plant, such as Nicotiana tabacum, and we hypothesize that endocytosis contributes to the uptake of uranium in tobacco. The endocytic uptake of uranium was investigated in tobacco BY 2 cells using an optimized setup of culture in phosphate-deficient medium. A combination of methods in biochemistry, microscopy and spectroscopy, supplemented by proteomics, were used to study the interaction of uranium and the plant cell. We found that under environmentally relevant uranium concentrations, endocytosis remained active and contributed to 14% of the total uranium bioassociation. Proteomics analyses revealed that uranium induced a change in expression of the clathrin heavy chain variant, signifying a shift in the type of endocytosis taking place. However, the rate of endocytosis remained largely unaltered. Electron microscopy and energy dispersive X-ray spectroscopy showed an adsorption of uranium to cell surfaces and deposition in vacuoles. Our results demonstrate that endocytosis constitutes a considerable proportion of uranium uptake in BY 2 cells, and that endocytosed uranium is likely targeted to the vacuole for sequestration, providing a physiologically safer route for the plant than uranium transported through the cytosol.

Published
2022

41. A method for independent modelling in support of regulatory review of dose assessments.

Author

Dverstorp, Björn and Xu, Shulan

Subjects
*RADIATION doses, *RADIOACTIVE waste disposal in the ground, *NUCLEAR fuels & the environment, *RADIATION safety officers, *BIOSPHERE
Abstract

Several countries consider geological disposal facilities as the preferred option for spent nuclear fuel due to their potential to provide isolation from the surface environment on very long timescales. In 2011 the Swedish Nuclear Fuel & Waste Management Co. (SKB) submitted a license application for construction of a spent nuclear fuel repository. The disposal method involves disposing spent fuel in copper canisters with a cast iron insert at about 500 m depth in crystalline basement rock, and each canister is surrounded by a buffer of swelling bentonite clay. SKB's license application is supported by a post-closure safety assessment, SR-Site. SR-Site has been reviewed by the Swedish Radiation Safety Authority (SSM) for five years. The main method for review of SKB's license application is document review, which is carried out by SSM's staff and supported by SSM's external experts. The review has proven a challenging task due to its broad scope, complexity and multidisciplinary nature. SSM and its predecessors have, for several decades, been developing independent models to support regulatory reviews of post-closure safety assessments for geological repositories. For the review of SR-Site, SSM has developed a modelling approach with a structured application of independent modelling activities, including replication modelling, use of alternative conceptual models and bounding calculations, to complement the traditional document review. This paper describes this scheme and its application to biosphere and dose assessment modelling. SSM's independent modelling has provided important insights regarding quality and reasonableness of SKB's rather complex biosphere modelling and has helped quantifying conservatisms and highlighting conceptual uncertainty. [ABSTRACT FROM AUTHOR]

Published
2017
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42. Radionuclide transport model for risk evaluation of high-level radioactive waste in Northwestern China.

Author

Cao, Xiaoyuan, Hu, Litang, Wang, Jinsheng, and Wang, Jingrui

Subjects
*GROUNDWATER pollution, *RADIOISOTOPES, *RADIOACTIVE wastes, *ECOLOGICAL risk assessment, *PLUMES (Fluid dynamics), *HYDROGEOLOGY, *GROUNDWATER recharge
Abstract

The proper disposal of high-level radioactive waste (HLRW) is highly challenging. Numerical simulations are helpful methods of evaluating the risks of radionuclide transport. This paper examines the hydrogeological conditions of a prospective HLRW repository in China. A regional radionuclide transport model is first constructed using the TOUGH2-MP/EOS7R module at a site in northwestern China to evaluate radionuclide transport behavior. A flow model calibration under a steady state shows that the simulated and observed hydraulic heads match well. Hypothetical radionuclides (90Sr,137Cs,235U and239Pu) are assumed to be instantaneously released at three locations with large groundwater velocities. Transport modeling shows that235U is the most sensitive element and has the plume size (2400 m) after 10,000 years. Sensitivity analyses of parameters, including the permeability, distribution coefficient and diffusion coefficient, are carried out. The results show that the distribution coefficient is the most critical parameter for nuclide transport. These findings will provide a preliminary reference for the radionuclide migration process at a prospective HLRW disposal site, which could be informative for safety analyses and further transport in and around the repository system. [ABSTRACT FROM PUBLISHER]

Published
2017
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43. Coupling of unsaturated zone and saturated zone in radionuclide transport simulations.

Author

Testoni, Raffaella, Levizzari, Riccardo, and De Salve, Mario

Subjects
*RADIOISOTOPES, *COUPLING constants, *ZONE of aeration, *SOFTWARE development tools, *HYDROGEOLOGY
Abstract

In the management of radionuclide release in the environment, the unsaturated zone could be a natural barrier to delay or to stop the radionuclide migration through the environment and to protect the groundwater from radiological risks. Thus, a suitable scientific evaluation of any radionuclide transport problems related to groundwater may to take into account the processes affecting flow through the unsaturated zone. In this work, an approach that involves the interactions between unsaturated zone and saturated zone both from hydrogeological and radionuclide transport point of view is proposed. This approach was tested developing a case study on an Italian nuclear site. The behavior of unsaturated zone as protective barrier for the groundwater was highlighted and identified as a fundamental aspect in the development of environmental analysis concerning the radionuclide transport into the environment. Promising results were found to improve the design of a radiological monitoring network. [ABSTRACT FROM AUTHOR]

Published
2017
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44. Microbial impacts on 99mTc migration through sandstone under highly alkaline conditions relevant to radioactive waste disposal.

Author

Smith, Sarah L., Boothman, Christopher, Williams, Heather A., Ellis, Beverly L., Wragg, Joanna, West, Julia M., and Lloyd, Jonathan R.

Subjects
*SANDSTONE, *RADIOACTIVE wastes, *WASTE management, *SODIC soils, *HYDRAULIC conductivity
Abstract

Geological disposal of intermediate level radioactive waste in the UK is planned to involve the use of cementitious materials, facilitating the formation of an alkali-disturbed zone within the host rock. The biogeochemical processes that will occur in this environment, and the extent to which they will impact on radionuclide migration, are currently poorly understood. This study investigates the impact of biogeochemical processes on the mobility of the radionuclide technetium, in column experiments designed to be representative of aspects of the alkali-disturbed zone. Results indicate that microbial processes were capable of inhibiting 99m Tc migration through columns, and X-ray radiography demonstrated that extensive physical changes had occurred to the material within columns where microbiological activity had been stimulated. The utilisation of organic acids under highly alkaline conditions, generating H 2 and CO 2 , may represent a mechanism by which microbial processes may alter the hydraulic conductivity of a geological environment. Column sediments were dominated by obligately alkaliphilic H 2 -oxidising bacteria, suggesting that the enrichment of these bacteria may have occurred as a result of H 2 generation during organic acid metabolism. The results from these experiments show that microorganisms are able to carry out a number of processes under highly alkaline conditions that could potentially impact on the properties of the host rock surrounding a geological disposal facility for intermediate level radioactive waste. [ABSTRACT FROM AUTHOR]

Published
2017
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45. Implications of Grain-Scale Mineralogical Heterogeneity for Radionuclide Transport in Fractured Media.

Author

Trinchero, Paolo, Molinero, Jorge, Deissmann, Guido, Svensson, Urban, Gylling, Björn, Ebrahimi, Hedieh, Hammond, Glenn, Bosbach, Dirk, and Puigdomenech, Ignasi

Subjects
RADIOISOTOPES, RADIOACTIVE waste disposal, MICROSTRUCTURE, DARCY'S law, CESIUM
Abstract

The geological disposal of nuclear waste is based on the multi-barrier concept, comprising various engineered and natural barriers, to confine the radioactive waste and isolate it from the biosphere. Some of the planned repositories for high-level nuclear waste will be hosted in fractured crystalline rock formations. The potential of these formations to act as natural transport barriers is related to two coupled processes: diffusion into the rock matrix and sorption onto the mineral surfaces available in the rock matrix. Different in situ and laboratory experiments have pointed out the ubiquitous heterogeneous nature of the rock matrix: mineral surfaces and pore space are distributed in complex microstructures and their distribution is far from being homogeneous (as typically assumed by Darcy-scale coarse reactive transport models). In this work, we use a synthetically generated fracture-matrix system to assess the implications of grain-scale physical and mineralogical heterogeneity on cesium transport and retention. The resulting grain-scale reactive transport model is solved using high-performance computing technologies, and the results are compared with those derived from two alternative models, denoted as upscaled models, where mineral abundance is averaged over the matrix volume. In the grain-scale model, the penetration of cesium into the matrix is faster and the penetration front is uneven and finger-shaped. The analysis of the cesium breakthrough curves computed at two different points in the fracture shows that the upscaled models provide later first-arrival time estimates compared to the grain-scale model. The breakthrough curves computed with the three models converge at late times. These results suggest that spatially averaged upscaled parameters of sorption site distribution can be used to predict the late-time behavior of breakthrough curves but could be inadequate to simulate the early behavior. [ABSTRACT FROM AUTHOR]

Published
2017
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46. Impacts of Preferential Flow on Tc-99and Np-237 Vadose Transport in Soils at the Savannah River Site

Author

Parris, Josh

Subjects
Preferential flow, vadose zone, unsaturated flow, macropore flow, macropore network, capillary exclusion, radionuclide transport, technetium-99, Tc-99, neptunium-237, Np-237, bromine, bromide, Br, Savannah River Site, SRS, non-equilibrium transport, residence time distribution analysis, RTD, temporal moments analysis, spatial moments analysis, two-region non-equilibrium transport model, mobile-immobile model, MIM, mobile-fluid region, immobile-fluid region, convection-dispersion equation, CDE, spent nuclear fuel storage, SNF, dispersivity, mobile water fraction, mass transfer coefficient, CXTFIT, pore volume, sandy clay loam, sand, soil, sorption, partitioning coefficient, Kd, column flow experiment, column tracer test, mean arrival time, MAT, mean travel time, MTT mean arrival pore volume, MAPV, mean travel pore volume, MTPV, retardation factor, CT scanner, MILabs, U-CT scanner, soil structures, 3D macropore network reconstruction, heterogeneity, and effluent., Environmental Chemistry, Environmental Engineering, Environmental Health and Protection, Environmental Indicators and Impact Assessment, Geochemistry, Inorganic Chemistry, Radiochemistry, Soil Science
Abstract

Since the 1950s, the United States has produced approximately 90,000 metric tons of spent nuclear fuel (SNF) (Office of Nuclear Energy, 2022); however, no long-term storage solutions are available. Technecium-99 and neptunium-237, two fission products found in SNF, readily form highly mobile species in oxidizing conditions (Hu, 2008; Bondietti, 1979) and have respective half-lives of 2.13 x 105 and 2.14 x106 years (Hu, 2010). Considering these characteristics, 99Tc and 237Np are two risk-driving isotopes found in SNF storage. The process of macropore-facilitated preferential flow, transport through cracks within a soil matrix, has been recognized to increase radionuclide mobility (Bundt, 2000). The aim of this study is to clarify the influence of macropore structures (orientation and geometry) on the transport of 99Tc and 237Np in unsaturated sand and sandy clay loam (SCL) soils. Unsaturated column flow experiments were completed with Br (tracer), 99Tc, and 237Np on homogeneous and macroporous soil columns. CT scans of soil columns were acquired to generate 2D and 3D imaging of macropore networks. Retardation factors for Tc99 breakthrough were 1.30 in homogeneous SCL and ranged from 1.28 to 1.41 in macroporous SCL, indicating that macropore-facilitated bypass flow is limited in unsaturated conditions. However, 99Tc exhibited earlier initial arrival (IBV) and longer attenuation in macroporous SCL soils. Increasing dispersivity estimates, determined by fitting the two-region nonequilibrium convection dispersion equation (MIM), well describe the anomalous breakthrough trends observed in macroporous SCL soils. From these findings, we conclude that macropore structures oriented transverse to unsaturated flow act as capillary barriers (resulting in longer radionuclide attenuation). If vertically oriented, macropore structures act as capillary boundaries that isolate matrix flow to a fraction of the pore network (increasing the average porewater velocity and IBV).

Published
2023

48. Endocytosis is a significant contributor to uranium(VI) uptake in tobacco (Nicotiana tabacum) BY-2 cells in phosphate-deficient culture

Author

Warren A. John, Benita Lückel, Nicole Matschiavelli, René Hübner, Susanne Matschi, Wolfgang Hoehenwarter, and Susanne Sachs

Subjects
inorganic chemicals, Environmental Engineering, radionuclide transport, technology, industry, and agriculture, Biological Transport, heavy metal interaction, Pollution, complex mixtures, Endocytosis, Phosphates, vesicle uptake, proteomics, Tobacco, Uranium, Environmental Chemistry, Waste Management and Disposal, plant cell
Abstract

Endocytosis of metals in plants is a growing field of study involving metal uptake from the rhizosphere. Uranium, which is naturally and artificially released into the rhizosphere, is known to be taken up by certain species of plant, such as Nicotiana tabacum, and we hypothesize that endocytosis contributes to the uptake of uranium in tobacco. The endocytic uptake of uranium was investigated in tobacco BY-2 cells using an optimized setup of culture in phosphate-deficient medium. A combination of methods in biochemistry, microscopy and spectroscopy, supplemented by proteomics, were used to study the interaction of uranium and the plant cell. We found that under environmentally relevant uranium concentrations, endocytosis remained active and contributed to 14% of the total uranium bioassociation. Proteomics analyses revealed that uranium induced a change in expression of the clathrin heavy chain variant, signifying a shift in the type of endocytosis taking place. However, the rate of endocytosis remained largely unaltered. Electron microscopy and energy-dispersive X-ray spectroscopy showed an adsorption of uranium to cell surfaces and deposition in vacuoles. Our results demonstrate that endocytosis constitutes a considerable proportion of uranium uptake in BY-2 cells, and that endocytosed uranium is likely targeted to the vacuole for sequestration, providing a physiologically safer route for the plant than uranium transported through the cytosol.

Published
2022

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