Abstract
Time-resolved luminescence spectroscopy is usefully used to identify U(VI) surface species adsorbed on SiO2. However, the cause of the inconsistent luminescence lifetimes and spectral shapes reported previously remains undetermined. In this study, the U(VI) surface coverage (Γ) and excitation laser wavelength (λex) were examined as the predominant factors governing the luminescence properties of U(VI) surface species. At neutral pH, the luminescence lifetimes of U(VI) surface species increased with decreasing Γ. In the low-Γ region, where a relatively large number of adjacent surface sites are involved in the formation of multidentate surface complexes, the displacement of more number of coordinated water molecules in the equatorial plane of U(VI) results in a longer lifetime. The pH-dependent luminescence lifetimes of U(VI) surface species at the same U(VI) to SiO2 concentration ratio in the pH range of 4.5–7.5 also explain the effect of the surface binding sites on the luminescence lifetime. The time-resolved luminescence properties of the U(VI) surface species were also investigated at different excitation wavelengths. Continued irradiation of the SiO2 surface with a UV laser beam at λex = 266 nm considerably reduced the luminescence intensities of the U(VI) surface species. The higher the laser pulse energy, the greater the decrease in luminescence intensity. Laser-induced thermal desorption (LITD) of U(VI) surface species is suggested to be the origin of the decrease in luminescence intensity. LITD effects were not observed at λex = 355 and 422 nm, even at high laser pulse energies.
Highlights
Mobile uranium exists in the hexavalent oxidation state (U(VI)) under oxic conditions
For the luminescence measurement of U(VI) surface species at pH 4.0, the aqueous U(VI) species were removed by centrifugation, after which the separated SiO2 particles were resuspended in a fresh background NaClO4 solution with a pH and an ionic strength idenMinerals 2022, 12, x FOR PEER REVIEtWical to the original ones but without U(VI)
The U(VI)-hydroxo surface species are likely highly coordinated by SiO2 in the low Γ region, where a relatively large number of adjacent surface sites are involved in surface complexation
Summary
Mobile uranium exists in the hexavalent oxidation state (U(VI)) under oxic conditions. The adsorption characteristics of U(VI) onto SiO2 surfaces have been investigated at the molecular scale using spectroscopic techniques, such as extended X-ray absorption fine structure (EXAFS) spectroscopy [8,9,10,11,12], X-ray photoelectron spectroscopy [13,14], and time-resolved laser-induced fluorescence spectroscopy (TRLFS) [13,14,15,16,17,18,19,20,21,22,23,24]. A comparison of the spectra in Figure 8 with those in the right lower panel of Figure 10 reveals that there are no additional U(VI) species in the low SSA sample
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