The present study reports the acid-free, ligand-free, fast room-temperature dissolution of UO3 in an ionic liquid (C4mimPF6: 1-butyl-3-methylimidazolium hexafluorophosphate) with subsequent electrodeposition, demonstrating the feasibility of sustainable, environmentally benign, nonaqueous processing of uranium trioxide under chemically and thermally mild conditions via in situ fluoride generation. The solubility of uranium oxides follows the trend UO3 > U3O8 > UO2. The endothermic behavior of the dissolution was confirmed through calorimetric investigation. The dissolution of UO3 followed pseudo-first-order behavior, with an activation energy of ∼52.2 kJ mol-1. Only 2 h was required to achieve the quantitative and selective dissolution of UO3, resulting in a solution of concentration 5 mg/mL with separation factors in the range of 3.1 × 102-6.9 × 102 with respect to trivalent lanthanide oxides and 2.3 × 103-6.9 × 103 with respect to CuO and Pr6O11. The cyclic voltamogram exhibited a single reduction peak at -0.6 V, indicating the reduction of uranium from (VI) to (V); however, no analogous oxidation peaks in the anodic sweep were observed, revealing irreversible redox behavior. The dissolved uranium was electrochemically recovered from the ionic liquid phase onto a copper plate, resulting in a black deposit of UO2, as confirmed by XRD, EDXRF, and FTIR analyses.
Karmakar et al. (Fri,) studied this question.