Issue 33, 2024

Reductive hydrothermal conversion of uranyl oxalates into UO2+x monitored by in situ XANES analyses

Abstract

Hydrothermal conversion of actinide oxalates has recently gained attention as an innovative fabrication route for nuclear fuels but has remained mainly limited to tetra- or tri-valent cations. We report herein the reductive conversion of mixtures of uranyl and oxalate ions into UO2+x oxides under mild hydrothermal conditions (T = 250 °C). A multi-parametric study first led to specifying the optimal conditions in terms of pH, oxalate/U ratio and duration to provide a quantitative precipitation of uranium in the hyper-stoichiometric dioxide form with pH = 0.8; R = noxalate/nU = 3, and t = 72 hours. Particularly, pH was evidenced as a key parameter, with 3 different compounds obtained over a range of only 0.4 units. The mechanism leading to the formation of UO2+x was then investigated thanks to an in situ XANES study. Analysis of the supernatant showed that U(VI) was quickly reduced into U(IV) thanks to the presence of oxalates and/or their decomposition products in solution, following first-order kinetics. Tetravalent uranium was then hydrolysed, leading to the precipitation of UO2+x as the only crystalline phase. This study thus demonstrates that the hydrothermal conversion of actinide oxalates into oxides is an extremely versatile tool that can be implemented in a large variety of chemical systems, particularly in terms of the oxidation state of the cations initially present in solution.

Graphical abstract: Reductive hydrothermal conversion of uranyl oxalates into UO2+x monitored by in situ XANES analyses

Supplementary files

Article information

Article type
Paper
Submitted
17 May 2024
Accepted
23 Jul 2024
First published
05 Aug 2024
This article is Open Access
Creative Commons BY license

Dalton Trans., 2024,53, 13982-13995

Reductive hydrothermal conversion of uranyl oxalates into UO2+x monitored by in situ XANES analyses

S. Benarib, M. Munoz, I. Kieffer, J. Hazemann, N. Dacheux and N. Clavier, Dalton Trans., 2024, 53, 13982 DOI: 10.1039/D4DT01451K

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