RTM for Waste Repositories

Bildstein, Olivier; Claret, Francis; Frugier, Pierre

doi:10.2138/rmg.2019.85.14

Cited by 25 publications

(13 citation statements)

References 270 publications

(280 reference statements)

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“…Appropriate numerical simulations using highly developed and augmented reactive transport codes are an essential ingredient of the longterm performance assessment of nuclear waste repositories. 28,29,[60][61][62][63][64][65] A serious weakness in the current knowledge base is the lack of reliable temperature dependent thermodynamic information for the most important chemical species and chemical reactions involved. 31,[66][67][68] The elaboration of a complete chemical thermodynamic database 27,28,69,70 is mandatory if we desire to bring the results of such simulations in agreement with the experimental information.…”

Section: Introductionmentioning

confidence: 99%

Full crystal structure, hydrogen bonding and spectroscopic, mechanical and thermodynamic properties of mineral uranopilite

et al. 2020

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Section: Introductionmentioning

confidence: 99%

Full crystal structure, hydrogen bonding and spectroscopic, mechanical and thermodynamic properties of mineral uranopilite

et al. 2020

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“…Modeling in ACED is based on so-called continuum modeling, in which the flow and transport of solutes (and possible gases) by diffusion and advection are coupled with thermodynamic and kinetic models to represent the geochemical state. Such models are typically called coupled reactive transport models [6], and although they have already been available for several decades, their recent capabilities now allow them to handle complex environmental and engineering problems, including radioactive waste disposal [7,8]. Beside the reactive transport codes themselves, and the variety of geochemical processes under different conditions (e.g.…”

Section: Assessment Of the Chemical Evolution At Disposal Cell Scale ...mentioning

confidence: 99%

Modelling of the long-term evolution and performance of engineered barrier system

Claret

Jacques²,

Sellin

2022

EPJ Nuclear Sci. Technol.

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Components of the so-called “multiple-barrier system” from the waste form to the biosphere include a combination of waste containers, engineered barriers, and natural barriers. The Engineered Barrier System (EBS) is crucial for containment and isolation in a radioactive waste disposal system. The number, types, and assigned safety functions of the various engineered barriers depend on the chosen repository concept, the waste form, the radionuclides waste inventory, the selected host rock, and the hydrogeological and geochemical settings of the repository site, among others. EBS properties will evolve with time in response to the thermal, hydraulic, mechanical, radiological, and chemical gradients and interactions between the various constituents of the barriers and the host rock. Therefore, assessing how these properties evolve over long time frames is highly relevant for evaluating the performance of a repository system and safety function evaluations in a safety case. For this purpose, mechanistic numerical models are increasingly used. Such models provide an excellent way for integrating into a coherent framework a scientific understanding of coupled processes and their consequences on different properties of the materials in the EBS. Their development and validation are supported by R&D actions at the European level. For example, within the HORIZON 2020 project BEACON (Bentonite mechanical evolution), the development, test, and validation of numerical models against experimental results have been carried out in order to predict the evolution of the hydromechanical properties of bentonite during the saturation process. Also, in relation to the coupling with mechanics, WP16 MAGIC (chemo Mechanical AGIng of Cementitious materials) of the EURAD Joint Programming Initiative focuses on multi-scale chemo-mechanical modeling of cementitious-based materials that evolve under chemical perturbation. Integration of chemical evolution in models of varying complexity is a major issue tackled in the WP2 ACED (Assessment of Chemical Evolution of ILW and HLW Disposal cells) of EURAD. WP4 DONUT (Development and improvement of numerical methods and tools for modeling coupled processes) of EURAD aims at developing and improving numerical models and tools to integrate more complexity and coupling between processes. The combined progress of those projects at a pan-European level definitively improves the understanding of and the capabilities for assessing the long-term evolution of engineered barrier systems.

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“…Arguably, one of the most significant achievements in reactive transport analysis in recent years has been the application to multiphase systems, including soils and the deep vadose zone where mostly water and air coexist (Dwivedi et al 2019;Arora et al 2019, both this volume), and the deep subsurface where other fluids and gases may be present (e.g., oil, gas, steam). It is well beyond the scope of this contribution to review these, but some discussion can be found in Sin and Corvisier (2019) and in Bildstein et al (2019), both this volume. This is a challenging topic because of the presence of different phases, each of which has its own transport and chemical properties, and because of the complex, typically time-dependent interfaces between the phases.…”

Section: Multiphase Reactive Systemsmentioning

confidence: 99%

Reactive Transport at the Crossroads

Steefel

2019

Reviews in Mineralogy and Geochemistry

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RTM for Waste Repositories

Abstract: ILLW in clay formation Clay-atmospheric O 2 Construction phase (disposal cell) Bentonite handling and emplacement Construction phase (disposal cell) Concrete-atmospheric CO 2 Construction and ventilation phase (wells, tunnel)

Cited by 25 publications

References 270 publications

Full crystal structure, hydrogen bonding and spectroscopic, mechanical and thermodynamic properties of mineral uranopilite

Full crystal structure, hydrogen bonding and spectroscopic, mechanical and thermodynamic properties of mineral uranopilite

Modelling of the long-term evolution and performance of engineered barrier system

Reactive Transport at the Crossroads

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