RES³T - Rossendorf Expert System for Surface and Sorption Thermodynamics

The mechanism of U(VI) sorption on montmorillonite (Na-SWy-1) in the absence and presence of carbonate was investigated through a combination of different approaches: macroscopic sorption experiments, surface complexation modelling using the 2 Site Protolysis Non Electrostatic Surface Complexation and Cation Exchange sorption model and Extended X-ray Absorption Fine Structure (EXAFS) spectroscopy. U(VI) sorption measurements were performed in the absence of carbonate at fixed ionic strength (0.1 M NaClO₄) as a function of pH at U(VI) trace concentration (∼9 × 10⁻⁸ M) and as a function of U(VI) concentration (∼10⁻⁷–10⁻⁴ M) at a fixed pH (5, 6.8 and 8). In the presence of carbonate, experiments were carried out in equilibrium with atmospheric pCO₂ and in 1, 3 and 5 mM NaHCO₃. The pH dependent sorption measurements at trace concentration in the absence of carbonate were modelled by considering the formation of the following surface species, ≡S^SOUO₂⁺, ≡S^SOUO₂OH⁰, ≡S^SOUO₂(OH)₂⁻ and ≡S^SOUO₂(OH)₃²⁻ on the strong sites. From the isotherms the formation of ≡S^W1OUO₂⁺ and ≡S^W1OUO₂OH⁰ on the weak sites was inferred. Two additional surface complexes on the strong sites, ≡S^SOUO₂CO₃⁻ and ≡S^SOUO₂(CO₃)₂³⁻ and one surface complex on the weak sites, ≡S^W1OUO₂CO₃⁻ , were necessary to reproduce the sorption data obtained in the presence of carbonate. The EXAFS measurements did not allow to verify the formation of ternary uranyl-carbonate complexes on the montmorillonite surface. However, the obtained fit results, i.e. splitting of the equatorial oxygen shell, one Si/Al shell at ∼3.09 Å and one Si/Al at ∼3.29 Å or one Fe shell at ∼3.42 Å, clearly indicate that under the given experimental conditions (pH, U(VI) loading) U(VI) forms inner-sphere surface complexes on montmorillonite edge sites via binding to aluminum octahedra and/or silicon tetrahedra.