In this study, the complexation of Eu(III) and Cm(III) with aqueous phosphates was investigated using laser-induced luminescence spectroscopy. Experiments at 25 °C and different ionic strengths (0.6-3.1 mol·L NaClO) established the formation of EuHPO and CmHPO. From the conditional stability constants, the respective values at infinite dilution as well as the ε(Me(HPO);ClO) (Me = Eu or Cm) ion interaction coefficients (using the specific ion interaction theory - SIT) were derived. Further experiments (at constant ionic strength of 1.1 mol·L) showed that upon increasing the temperature (25-80 °C), the formation of both EuHPO and CmHPO was favored. Using the van't Hoff equation, the molal enthalpy Δ H and molal entropy Δ S of these reactions were derived, corroborating an endothermic and entropy driven complexation process. This work contributes to a better understanding of the coordination chemistry of both trivalent lanthanides and actinides with phosphate ions.
Uranyl(vi) complexation with fluoride and chloride was investigated with luminescence spectroscopy, and the strong quenching by chloride was overcome by freezing.
The
interaction of Eu(III) with thin sections of migmatized gneiss
from the Bukov Underground Research Facility (URF), Czech Republic,
was characterized by microfocus time-resolved laser-induced luminescence
spectroscopy (μTRLFS) with a spatial resolution of ∼20 μm, well below typical grain
sizes of the
material. By this approach, sorption processes can be characterized
on the molecular level while maintaining the relationship of the speciation
with mineralogy and topography. The sample mineralogy was characterized
by powder X-ray diffraction and Raman microscopy, and the sorption
was independently quantified by autoradiography using 152Eu. Representative μTRLFS studies over large areas of multiple
mm2 reveal that sorption on the heterogeneous material
is not dominated by any of the typical major constituent minerals
(quartz, feldspar, and mica). Instead, minor phases such as chlorite
and prehnite control the Eu(III) distribution, despite their low contribution
to the overall composition of the material, as well as common but
less studied phases like Mg–hornblende. In particular, prehnite
shows high a sorption uptake as well as strong binding of Eu to the
mineral surface. Sorption on prehnite and hornblende happens at the
expense of feldspar, which showed the highest sorption uptake in a
previous spatially resolved study on granitic rock. Similarly, sorption
on quartz is reduced, even though only low quantities of strongly
bound Eu(III) were found here previously. Our results illustrate how
competition of mineral surfaces for adsorbing cations drives the metal
distribution in heterogeneous systems.
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