Denise Adorno Lopes scite author profile

Uranium nitride (UN) is a candidate fuel for current GEN III fission reactors, for which it is investigated as an accident-tolerant fuel, as well as for future GEN IV reactors. In this study, we investigate the kinetic properties of gas fission products (Xe and Kr) in UN. Binding and migration energies are obtained using density functional theory, with an added Hubbard correlation to model f -electrons, and the Occupation Matrix Control scheme to avoid metastable states. These energies are then used as input for the Self-Consistent Mean Field method which enables to determine transport coefficients for vacancy-mediated diffusion of Xe and Kr on the U-sublattice. The magnetic ordering of the UN structure is explicitly taken into account, for both energetic and transport properties. Solute diffusivities are compared with experimental measurements and the effect of various parameters on the theoretical model is carefully investigated. We find that kinetic correlations are very strong in this system, and that despite atomic migration anisotropy, macroscopic solute diffusivities show limited anisotropy. Our model indicates that the discrepancy between experimental measurements probably results from different irradiation conditions, and hence different defect concentrations.

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Mechanical and thermal behaviour of U–Mo and U–Nb–Zr Alloys

Lopes¹,

Restivo²,

Padilha³

2013

Journal of Nuclear Materials

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Fabrication and microstructural analysis of UN-U3Si2 composites for accident tolerant fuel applications

Johnson

Raftery

Lopes

et al. 2016

Journal of Nuclear Materials

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Transport properties of C and O in UN fuels

et al. 2017

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Uranium nitride fuel is considered for fast reactors (GEN-IV generation and space reactors) and for light water reactors as a high-density fuel option. Despite this large interest, there is a lack of information about its behavior for in-pile and out-of-pile conditions. From the present literature, it is known that C and O impurities have significant influence on the fuel performance. Here, we perform a systematic study of these impurities in the UN matrix using electronic-structure calculations of solute-defect interactions and microscopic jump frequencies. These quantities were calculated in the DFT+U approximation combined with the occupation matrix control scheme, to avoid convergence to metastable states for the 5f levels. The transport coefficients of the system were evaluated with the self-consistent mean-field theory. It is demonstrated that carbon and oxygen impurities have different diffusion properties in the UN matrix, with O atoms having a higher mobility, and C atoms showing a strong flux coupling anisotropy. The kinetic interplay between solutes and vacancies is expected to be the main cause for surface segregation, as incorporation energies show no strong thermodynamic segregation preference for (001)-surfaces compared with the bulk.

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Oxidation of accident tolerant fuel candidates

Johnson

Ström²,

Wallenius

et al. 2016

Journal of Nuclear Science and Technology

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