Physics-based modelling and validation of inter-granular helium behaviour in SCIANTIX

Physics-based modelling and validation of inter-granular helium behaviour in SCIANTIX

In this work, we propose a new mechanistic model for the treatment of helium behaviour at the grain boundaries in oxide nuclear fuel. The model provides a rate-theory description of helium inter-granular behaviour, considering diffusion towards grain edges, trapping in lenticular bubbles, and therma...

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Bibliographic Details
Published in:Nuclear engineering and technology Vol. 54; no. 7; pp. 2367 - 2375
Main Authors: Giorgi, R., Cechet, A., Cognini, L., Magni, A., Pizzocri, D., Zullo, G., Schubert, A., Van Uffelen, P., Luzzi, L.
Format: Journal Article
Language:English
Published: Elsevier 01-07-2022
한국원자력학회
Subjects:
Fuel performance codes
Helium behaviour
Meso-scale modelling
Oxide nuclear fuel
SCIANTIX
원자력공학
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Summary:In this work, we propose a new mechanistic model for the treatment of helium behaviour at the grain boundaries in oxide nuclear fuel. The model provides a rate-theory description of helium inter-granular behaviour, considering diffusion towards grain edges, trapping in lenticular bubbles, and thermal re-solution. It is paired with a rate-theory description of helium intra-granular behaviour that includes diffusion towards grain boundaries, trapping in spherical bubbles, and thermal re-solution. The proposed model has been implemented in the meso-scale software designed for coupling with fuel performance codes SCIANTIX. It is validated against thermal desorption experiments performed on doped UO2 samples annealed at different temperatures. The overall agreement of the new model with the experimental data is improved, both in terms of integral helium release and of the helium release rate. By considering the contribution of helium at the grain boundaries in the new model, it is possible to represent the kinetics of helium release rate at high temperature. Given the uncertainties involved in the initial conditions for the inter-granular part of the model and the uncertainties associated to some model parameters for which limited lower-length scale information is available, such as the helium diffusivity at the grain boundaries, the results are complemented by a dedicated uncertainty analysis. This assessment demonstrates that the initial conditions, chosen in a reasonable range, have limited impact on the results, and confirms that it is possible to achieve satisfying results using sound values for the uncertain physical parameters.
ISSN:1738-5733
2234-358X
DOI:10.1016/j.net.2022.01.012