6533b85cfe1ef96bd12bc845
RESEARCH PRODUCT
Implementing first principles calculations of defect migration in a fuel performance code for UN simulations
Sergey N. RashkeevEugene A. KotominP. Van UffelenYu. A. Mastrikovsubject
Nuclear and High Energy PhysicsNuclear fuelChemistryNuclear engineeringComputation02 engineering and technologyActivation energyNuclear reactorNitride021001 nanoscience & nanotechnology01 natural sciences7. Clean energylaw.inventionNuclear physicsNuclear Energy and EngineeringCreep13. Climate actionlaw0103 physical sciencesBreeder reactorGeneral Materials Science010306 general physics0210 nano-technologyReduction (mathematics)description
Results are reported of first principles VASP supercell calculations of basic defect migration in UN nuclear fuels. The collinear interstitialcy mechanism of N migration is predicted to be energetically more favourable than direct [0 0 1] hops. It is also found that U and N vacancies have close migration energies, and O impurities accelerate migration of N vacancies nearby. These values are both in qualitative agreement with the effect of oxygen on the reduction of the activation energy for thermal creep reported in the literature, as well as in quantitative agreement with the experimental data when taking into account the uncertainties. The migration energies have been implemented in the thermal creep model of the TRANSURANUS fuel performance code. Therefore a concrete example is provided of how first principles computations can contribute directly to improve the design tools of advanced nuclear fuels, e.g. the predictions reveal a limited effect of oxygen on the thermo-mechanical performance of nitride fuels under fast breeder reactor (FBR) normal operating conditions.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2009-09-01 | Journal of Nuclear Materials |