Abstract
Brannerite, UTi2O6 is reported to occur in various uraniferous deposits worldwide. Natural brannerite specimens are found in the amorphous state and are usually considered to be refractory to dissolution due to the formation of TiO2 passivation layer. In the present work, brannerite was synthesized by wet chemistry route, then characterized prior the development of multiparametric dissolution experiments. The evolution of U and Ti concentrations was followed in 0.1–2 mol/L H2SO4 solutions, for temperatures ranging from 25 to 80 °C, in the presence (or not) of 2.8 g/L of dissolved Fe(III). The dissolution of synthetic brannerite was congruent in the whole experimental domain. The formation of Ti-enriched secondary phase at the surface of the brannerite grains was not evidenced. The dissolution rate constants, activation energies and partial orders of the overall dissolution reaction relative to proton activity were determined in the presence (or absence) of Fe(III). The introduction of Fe(III) in sulfuric acid solutions increased the dissolution rate constant by 5 orders of magnitude and induced significant modifications of the apparent activation energy (from 71 ± 4 to 91 ± 6 kJ/mol) and of the partial order relative to proton activity (from 0.42 ± 0.09 to 0.84 ± 0.08). This study suggested that the uncongruency of the brannerite dissolution and the changes usually observed in the rate-controlling step with temperature could be linked to the loss of the crystal structure in natural samples.
Highlights
The share of nuclear energy has been continuously growing in order to match the high demand of energy with low CO2 emission
From the results reported in the literature, it appeared that the complete recovery of uranium from brannerite could be reached within 1 h in 1 mol/L H2SO4 solution at high temperature (i.e ∼90 °C) and in the presence of 2.8 g/L (i.e., 0.05 mol/L) of Fe(III)[20]
At 25 and 45 °C, they showed a evolutions of the relative mass loss and of the normalized weight weak dependence of the uranium extraction on the redox potential while at 65 °C, the extent of uranium extraction reached a maximum at Eh = 460 mV vs. Ag/AgCl
Summary
The share of nuclear energy has been continuously growing in order to match the high demand of energy with low CO2 emission. Titanium was found to precipitate as anatase (TiO2) through the hydrolysis of TiO+(aq), which is thermodynamically favored at low pH This observation was consistent with the results obtained earlier by Costine et al.[29], who identified a strong correlation extraction from natural samples in sulfuric acid conditions and in the presence of Fe(III) used as an efficient oxidant of U(IV). These studies were of great importance to optimize U extraction from ores and strongly improved our understanding of the dissolution mechanism, dissolution rate laws were rarely established and when it was done, the kinetic parameters obtained appeared to be deposit-specific. The effect of redox potential was investigated by varying the Fe(II)/Fe(III) ratio at a
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