Affiliation:
1. Lawrence Berkeley National Laboratory, Berkeley, CA 94720, USA
2. Centro de Investigaciones Energéticas Medioambientales y Tecnológicas, 28040 Madrid, Spain
Abstract
Since nuclear energy is crucial in the decarbonization of the energy supply, one hurdle to remove is the handling of high-level radioactive waste (HLW). Disposal of HLW in a deep geological repository has long been deemed a viable permanent option. In the design of a deep geological repository, compacted bentonite is the most commonly proposed buffer material. Predicting the long-term chemical evolution in bentonite, which is important for the safety assessment of a repository, has been challenging because of the complex coupled processes. Models for large-scale tests and predictions based on such models have been some of the best practices for such purposes. An 18-year-long in situ test with two dismantling events provided a unique set of chemical data that allowed for studying chemical changes in bentonite. In this paper, we first developed coupled thermal, hydrological, mechanical, and chemical (THMC) models to interpret the geochemical data collected in the in situ test and then extended the THMC model to 200 years to make long-term prediction of the geochemical evolution of bentonite. The interpretive coupled THMC model shows that the geochemical profiles were strongly affected by THM processes such as evaporation/condensation, porosity change caused by swelling, permeability change, and the shape of concentration profiles for major cations were largely controlled by transport processes, but concentration levels were regulated by chemical reactions, and the profiles of some species such as pH, bicarbonate, and sulfate were dominated by these reactions. The long-term THMC model showed that heating prolongs the time that bentonite becomes fully saturated in the area close to the heater/canister; however, once the bentonite becomes fully saturated, high concentrations of ions in bentonite near the heater, which was observed in the field test, will disappear; illitization continues for 50 years but will not proceed further.
Funder
Spent Fuel and Waste Science and Technology, Office of Nuclear Energy, of the U.S. Department of Energy
Subject
Geology,Geotechnical Engineering and Engineering Geology
Reference45 articles.
1. Caporuscio, F.A., Sauer, K.B., and Rock, M.J. (2021). Technical Report by Los Alamos National Laboratory, Report Member: LA-UR-21-26538, Los Alamos National Lab. (LANL).
2. Experimental study of the transformation of smectite at 80 to 300 °C in the presence of Fe oxides;Guillaume;Clay Miner.,2004
3. Fe-saponite growth on low-carbon and stainless steel in hydrothermal-bentonite experiments;Cheshire;J. Nucl. Mater.,2018
4. Bentonite Clay evolution at elevated pressures and temperatures: An experimental study for generic nuclear repositories;Cheshire;Am. Mineral.,2014
5. Interaction processes at the concrete-bentonite interface after 13 years of FEBEX-Plug operation. Part II: Bentonite contact;Torres;Phys. Chem. Earth Parts A/B/C,2017