Insights into the Impact of Physicochemical and Microbiological Parameters on the Safety Performance of Deep Geological Repositories
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Morales-Hidalgo, Mar; Povedano-Priego, Cristina; Martinez-Moreno, Marcos F.; Ruiz Fresneda, Miguel Ángel; López-Fernández, Margarita; Jroundi, Fadwa; Merroun, Mohamed LarbiEditorial
MDPI
Materia
nuclear waste radiation; bentonite;
Date
2024-05-19Referencia bibliográfica
Morales Hidalgo, M. et. al. Microorganisms 2024, 12, 1025. [https://doi.org/10.3390/microorganisms12051025]
Sponsorship
PID2022-138402NB-C21 funded by MICIU/ AEI/10.13039/501100011033 and by ERDF/EU; FPU20/00583 to the first author from the Spanish GovernmentAbstract
Currently, the production of radioactive waste from nuclear industries is increasing, leading
to the development of reliable containment strategies. The deep geological repository (DGR) concept
has emerged as a suitable storage solution, involving the underground emplacement of nuclear
waste within stable geological formations. Bentonite clay, known for its exceptional properties,
serves as a critical artificial barrier in the DGR system. Recent studies have suggested the stability of
bentonite within DGR relevant conditions, indicating its potential to enhance the long-term safety
performance of the repository. On the other hand, due to its high resistance to corrosion, copper
is one of the most studied reference materials for canisters. This review provides a comprehensive
perspective on the influence of nuclear waste conditions on the characteristics and properties of
DGR engineered barriers. This paper outlines how evolving physico-chemical parameters (e.g.,
temperature, radiation) in a nuclear repository may impact these barriers over the lifespan of a
repository and emphasizes the significance of understanding the impact of microbial processes,
especially in the event of radionuclide leakage (e.g., U, Se) or canister corrosion. Therefore, this
review aims to address the long-term safety of future DGRs, which is critical given the complexity of
such future systems.