2012
DOI: 10.1103/physrevb.86.035110
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First-principles calculations of uranium diffusion in uranium dioxide

Abstract: The present work reports first-principles DFT+U calculations of uranium self-diffusion in uranium dioxide (UO2), with a focus on comparing calculated activation energies to those determined from experiments. To calculate activation energies, we initially formulate a point defect model for UO2±x that is valid for small deviations from stoichiometry. We investigate five migration mechanisms and calculate the corresponding migration barriers using both the LDA+U and GGA+U approximations. These energy barriers are… Show more

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Cited by 93 publications
(65 citation statements)
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“…The most likely mechanism was found to be a vacancy mechanism along the 111 direction and comprises an important influence of the oxygen sublattice. First-principles electronic computations yielded migration barriers of 3.6 eV (GGA + U model) or 4.8 eV (LDA + U model) [66]. These values can be compared with the experimental-based values listed in Table 3, discussed above, or yet with another experimental work by Reimann and Lundy [67], which gave Q D = 4.3 eV.…”
Section: Effective Diffusivitymentioning
confidence: 87%
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“…The most likely mechanism was found to be a vacancy mechanism along the 111 direction and comprises an important influence of the oxygen sublattice. First-principles electronic computations yielded migration barriers of 3.6 eV (GGA + U model) or 4.8 eV (LDA + U model) [66]. These values can be compared with the experimental-based values listed in Table 3, discussed above, or yet with another experimental work by Reimann and Lundy [67], which gave Q D = 4.3 eV.…”
Section: Effective Diffusivitymentioning
confidence: 87%
“…The mechanisms for uranium self-diffusion in UO 2 are detailed in a recent study by Dorodo et al [66]. The most likely mechanism was found to be a vacancy mechanism along the 111 direction and comprises an important influence of the oxygen sublattice.…”
Section: Effective Diffusivitymentioning
confidence: 99%
“…From both simulations [4,37,38] and experiments [39][40][41] it is clear that oxygen (O) vacancies and interstitials move several orders of magnitude faster through the UO 2 lattice than cations or fission gases. The migration barriers for anion vacancies and interstitials are 0.5 [39,42] and 0.9-1.3 eV [39,42,43], respectively, while the lowest barrier for cations (a cluster of two U vacancies that can form under irradiation) is predicted to be 2.6 eV [4] and the barrier for migration of single U vacancies is 4.5-4.8 eV [4,38].…”
Section: Oxygen Interstitials and Vacanciesmentioning
confidence: 99%
“…Migration of U interstitials was recently investigated using DFT calculations [38] and the barrier was calculated to be 3.7 eV for the indirect interstitial mechanism, which is lower than the barrier for single U vacancies but about 1 eV higher than for clusters of U vacancies (see below). Under thermal equilibrium conditions the contribution from interstitials to cation diffusion is very small due to the negligible concentration of such defects compared to vacancies [38].…”
Section: Uranium Interstitials and Vacanciesmentioning
confidence: 99%
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