Adsorption of CsCl on porous SiO2 glass surface: experimental results and ab-initio calculations

The disposal of nuclear wastes is an issue of global concern due to the physicochemical and radiologic properties of some isotopes. Cesium radionuclides exhibit high solubility and some of them pose a long half-life. This work focuses on the study of Cs+ adsorption on the surface of a porous silica...

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Bibliographic Details
Published in:Journal of non-crystalline solids 2016-05, Vol.440, p.70-75
Main Authors: Lago, D.C., Nuñez, M., Prado, M.O.
Format: Article
Language:English
Subjects:
Adsorption
Atomic absorption analysis
Charge transfer
Density functional
Glass
Half life
Mathematical analysis
Porous silica
Silica glass
Spectroscopy
Surface chemistry
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Summary:The disposal of nuclear wastes is an issue of global concern due to the physicochemical and radiologic properties of some isotopes. Cesium radionuclides exhibit high solubility and some of them pose a long half-life. This work focuses on the study of Cs+ adsorption on the surface of a porous silica glass. Adsorption experiments were done at room temperature using aqueous solutions with concentrations of 0.1 and 0.5M of CsCl at pH=5 and surface area to volume of 0.1cm−1. In these conditions, 14 and 18mgCs/gSiO2 were adsorbed, respectively. The adsorbed quantity of Cs+ was determined by atomic absorption spectroscopy (AAS) analyzing the quantity of Cs+ contained in the solution before and after adsorption experiments. The Cs+/Cl− ratio at a glass cross section surface, determined by energy dispersive spectroscopy analysis, is near 6. In addition, first principle calculations were performed, in order to determine charge transfer and location of the active sites for Cs+ and Cl−. Adhesion energy values are presented, which explain the experimental values found for the Cs+/Cl− concentration ratio at the silica glass surface. The parameters calculated from experimental and ab-initio calculations results were used to explain the adsorption mechanism. •By combining experiments and ab-initio calculations we determined the favourable places for Cs+ attachment on SiO2 glass surfaces.•Charge transfer between Cs+ and Cl– atoms and the glass surface atoms was determined by DFT calculations and allows us to understand the ion adsorption phenomena.•We also obtained experimental data on Cs+ adsorption on silica surfaces, and correlated experimental with theoretical results.
ISSN:0022-3093
1873-4812
DOI:10.1016/j.jnoncrysol.2016.02.020