An improved model for the corrosion of used nuclear fuel inside a failed waste container under permanent disposal conditions

An improved model for the corrosion of used nuclear fuel inside a failed waste container under permanent disposal conditions

[Display omitted] •The corrosion of spent nuclear fuel in a failed waste container is modelled.•Alpha-radiolysis process is simulated using a full reaction set.•Corrosion of UO2 is largely influenced by steel corrosion products, Fe2+ and H2.•H2 concentrations required to completely suppress fuel cor...

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Bibliographic Details
Published in:Corrosion science Vol. 84; pp. 85 - 95
Main Authors: Wu, Linda, Qin, Zack, Shoesmith, David W.
Format: Journal Article
Language:English
Published: Kidlington Elsevier Ltd 01-07-2014
Elsevier
Subjects:
A. Carbon steel
Applied sciences
B. Modelling studies
C. Anodic dissolution
C. Interfaces
Corrosion
Corrosion environments
Exact sciences and technology
Metals. Metallurgy
A. Carbon steel
C. Interfaces
B. Modelling studies
C. Anodic dissolution
Radioactive waste
Electrochemical corrosion
Nuclear fuel
Waste disposal
Modeling
Container
Storage
Anodic dissolution
Carbon steel
Application
Interface
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Summary:[Display omitted] •The corrosion of spent nuclear fuel in a failed waste container is modelled.•Alpha-radiolysis process is simulated using a full reaction set.•Corrosion of UO2 is largely influenced by steel corrosion products, Fe2+ and H2.•H2 concentrations required to completely suppress fuel corrosion are calculated.•Influences of burnup and fuel age are examined. An improved model for nuclear fuel corrosion inside a failed waste container has been developed. The model considers the influence of the α-radiolysis products using a full radiolytic reaction set, and demonstrates that H2O2 is the dominant oxidant. Corrosion of the fuel is modelled considering both the direct oxidation of UO2 by H2O2 and the galvanically-coupled oxidation by H2O2 reduction on noble metal (ε) particles. Corrosion has been found to be very sensitive to the corrosion products of steel container, Fe2+ and H2. The surface coverage of ε-particles can significantly influence the dissolution rate.
ISSN:0010-938X
1879-0496
DOI:10.1016/j.corsci.2014.03.019