Dissolution of Th0.25U0.75O2 sintered pellets: Impact of nitrate ions and nitrous acid
In order to gain insights on the kinetics of the dissolution of Gen(IV) MOX fuels, sintered pellets of Th0.25U0.75O2 were prepared as surrogates. Particularly, the impact of nitrogen species on the kinetics of dissolution of Th1-xUxO2 in nitric acid must be evaluated. In this work, various experimen...
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Veröffentlicht in: | Hydrometallurgy 2021-09, Vol.204, p.105717, Article 105717 |
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Zusammenfassung: | In order to gain insights on the kinetics of the dissolution of Gen(IV) MOX fuels, sintered pellets of Th0.25U0.75O2 were prepared as surrogates. Particularly, the impact of nitrogen species on the kinetics of dissolution of Th1-xUxO2 in nitric acid must be evaluated. In this work, various experiments were performed to determine the influence of nitrate ions and nitrous acid on the dissolution rate and mechanism of Th0.25U0.75O2 in nitric acid. It appeared that the addition of 3 mol L−1 NH4NO3 to the 1 mol L−1 HNO3 solution led to a strong increase of the dissolution rate. Thus, it seemed that the greatest impact on the dissolution kinetics during the induction period was associated to undissociated HNO3 instead of free nitrate ions. What is more, addition of a constant HNO2 concentration of 2 × 10−3 mol L−1 to 1 mol L−1 HNO3 induced a strong increase of the dissolution rate. However, the dissolution kinetics remained much faster in 4 mol L−1 HNO3, which was associated to the presence of an equivalent concentration of HNO2 in the solution. It then appeared that HNO2 species was not the prevailing species responsible for the catalysis of the dissolution kinetics of Th0.25U0.75O2. However, microstructural evolutions of the pellets dissolved in the presence of HNO2 showed the existence of small intra-granular corrosion pits covering the entire surface of the grains. That confirmed the highly oxidizing nature of HNO2 regarding to tetravalent uranium. Nevertheless, the presence of large cavities also suggested the existence of heterogeneous progress of the dissolution, associated to the existence of preferential dissolution zones consequently to the accumulation of reactive species in confined areas. Such reactive species might be HNO2, but more probably another unknown catalyst present at equilibrium with HNO2.
•The impact of nitrogen species on the dissolution kinetics of Th0.25U0.75O2 pellets has been underlined.•Undissociated HNO3 has the greatest impact on the dissolution kinetics during the induction period.•HNO2 is not the prevailing species responsible for the catalysis of the dissolution kinetics.•The formation of large cavities in the pellets underlines heterogeneous progress of the dissolution at the microscopic scale. |
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ISSN: | 0304-386X 1879-1158 |
DOI: | 10.1016/j.hydromet.2021.105717 |