Assessing the combined effect of gamma radiation and sulfate-reducing bacteria on copper corrosion for deep nuclear waste storage

Ensuring the integrity of containment barriers in geological disposal facilities (GDFs) is crucial for the long-term storage of radioactive waste. Copper is considered as a promising canister material due to its corrosion resistance. This study examines the combined effects of external gamma radiati...

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Bibliographic Details
Published in:Corrosion science Vol. 258; p. 113443
Main Authors: Morales-Hidalgo, Mar, Povedano-Priego, Cristina, Martinez-Moreno, Marcos F., Mumford, Adam D., Černá, Kateřina, Ju-Nam, Yon, Ojeda, Jesus J., Fernández, Ana María, Alonso, Ursula, Jroundi, Fadwa, Merroun, Mohamed L.
Format: Journal Article
Language:English
Published: Elsevier Ltd 01.01.2026
Subjects:
Deep geological repository
Geological disposal facility
Microbial activity
Microbially influenced corrosion
Nuclear waste repository
Spectroscopic characterization
Deep geological repository
Microbial activity
Nuclear waste repository
Spectroscopic characterization
Geological disposal facility
Microbially influenced corrosion
ISSN:0010-938X
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Summary:Ensuring the integrity of containment barriers in geological disposal facilities (GDFs) is crucial for the long-term storage of radioactive waste. Copper is considered as a promising canister material due to its corrosion resistance. This study examines the combined effects of external gamma radiation (14 and 28 kGy) and sulfate-reducing bacteria (SRB) on copper corrosion in highly compacted FEBEX bentonite. Results showed that gamma radiation significantly reduces SRB viability, suggesting that these bacteria are likely to remain inactive during the early centuries of GDF operation, when radiation is at its highest level. Microscopic and spectroscopic analyses identified copper oxides, particularly CuO, as the main corrosion products. Gamma radiation was found to delay microbially influenced corrosion by altering the microbial community structure and promoting salt precipitation, including copper sulfates. SRB facilitated the formation of biogenic copper sulfides on unirradiated samples or those minimally affected by radiation. These findings provide valuable insights into the role of SRB in copper corrosion, broadening the understanding of long-term GDF safety. [Display omitted] •Gamma radiation reduces SRB viability, delaying copper biocorrosion.•Copper oxides were the main corrosion products in all bentonite-treated blocks.•SRB-driven biogenic copper sulfides appeared in unirradiated treatments.•XPS revealed abiotic CuxS formation in Cu exposed to highest radiation dose (28 kGy).
ISSN:0010-938X
DOI:10.1016/j.corsci.2025.113443