Modelling nuclear fuel behaviour with TAF-ID: Calculations on the VERDON-1 experiment, representative of a nuclear severe accident

The chemical behaviour of the main elements present in a PWR irradiated fuel sample (UO2 fuel, Zr from the Zircaloy-cladding, Pu, Np, and fission products such as Ba, Ce, Cs, Gd, I, La, Mo, Nd, Pd, Rh, Ru, Sr, Tc, Te, etc.) submitted to a nuclear severe accident type sequence (VERDON-1 experiment) h...

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Bibliographic Details
Published in:Journal of nuclear materials 2019-08, Vol.522, p.294-310
Main Authors: Geiger, E., Guéneau, C., Pontillon, Y., Corcoran, E.C.
Format: Article
Language:English
Subjects:
Accidents
Atmospheric models
Barium
Chemical diffusion
Cladding
Experiments
Fission products
Gadolinium
Mass transport
Nuclear accidents & safety
Nuclear fuels
Nuclear severe accident
Organic chemistry
Physics
Pressurized water reactors
Strontium
TAF-ID
Temperature gradients
Thermodynamic modelling of nuclear fuel
Uranium dioxide
VERDON
Zircaloys (trademark)
Zirconium
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Summary:The chemical behaviour of the main elements present in a PWR irradiated fuel sample (UO2 fuel, Zr from the Zircaloy-cladding, Pu, Np, and fission products such as Ba, Ce, Cs, Gd, I, La, Mo, Nd, Pd, Rh, Ru, Sr, Tc, Te, etc.) submitted to a nuclear severe accident type sequence (VERDON-1 experiment) has been investigated by thermodynamic calculations using the TAF-ID database. Particular emphasis has been placed on the chemical behaviour of the fission products Ba, Cs, Mo, and Zr, and the interactions between the Zircaloy-cladding and the UO2 matrix. Calculation results have been compared to experimental observations completed during the VERDON-1 experiment (instantaneous release of fission products and final chemical state of elements in the sample). Results presented in this manuscript do not account for non-equilibrium phenomena that have a major impact on fission product behaviour (e.g., chemical diffusion, mass transport induced by temperature gradients in the fuel pellet, etc.). None the less, these TAF-ID calculations have described accurately the melting of the sample following the formation of a mixed (U,Zr)O2-x phase because of the interaction between the fuel and the Zircaloy-cladding. Furthermore, calculations have assisted in the explanation of the instantaneous released fractions observed for Ba and Mo during the experiment (as a function of the experiment atmosphere and temperature). •Fission products Ba, Cs, I, Mo, and the UO2 fuel – cladding interaction during a nuclear severe accident have been calculated with TAF-ID, and compared to experimental results.•Ba and Mo behavior were accurately reproduced, allowing to identify the chemical species that might have been released from the fuel.•TAF-ID calculations accurately predicted the fuel – cladding interactions, and the melting of the resulting solid solution by the end of the experiment.
ISSN:0022-3115
1873-4820
DOI:10.1016/j.jnucmat.2019.05.027