Hydrothermal synthesis of (Zr,U)SiO4: an efficient pathway to incorporate uranium into zircon

The preparation of synthetic (Zr,U)SiO4 solid solution is challenging, as the conventional high-temperature solid-state method limits the solubility of uranium (4 ± 1 mol%) in the orthosilicate phase due to its thermodynamic instability. However, these compounds are of great interest as a result of...

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Published in:Dalton transactions : an international journal of inorganic chemistry 2024-08, Vol.53 (33), p.13782-13794
Main Authors: Estevenon, Paul, Barral, Thomas, Avallone, Arthur, Mateo Jeffredo, De La Hos, Alexis, Strzelecki, Andrew, Xavier Le Goff, Szenknect, Stephanie, Kvashnina, Kristina, Moisy, Philippe, Podor, Renaud, Guo, Xiaofeng, Dacheux, Nicolas
Format: Article
Language:English
Subjects:
Argon
Chemical Sciences
Fourier transforms
High temperature
Hydrothermal treatment
Inert atmospheres
Infrared analysis
Metastable phases
Nuclear accidents
Purification
Radiochemistry
Solid solutions
Synthesis
Thermal stability
Thermodynamic properties
Thermogravimetric analysis
Uranium
X ray powder diffraction
Zircon
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Summary:The preparation of synthetic (Zr,U)SiO4 solid solution is challenging, as the conventional high-temperature solid-state method limits the solubility of uranium (4 ± 1 mol%) in the orthosilicate phase due to its thermodynamic instability. However, these compounds are of great interest as a result of (Zr,U)SiO4 solid solutions, with uranium contents exceeding this concentration, being observed as corium phases formed during nuclear accidents. It has been identified that hydrothermal synthesis pathways can be used for the formation of the metastable phase, such as USiO4. The investigation carried out in this study has indeed led to the confirmation of metastable (Zr,U)SiO4 compounds with high uranium contents being formed. It was found that (Zr,U)SiO4 forms a close-to-ideal solid solution with uranium loading of up to 60 mol% by means of hydrothermal treatment for 7 days at 250 °C, at pH = 3 and starting from an equimolar reactant concentration equal to 0.2 mol L−1. A purification procedure was developed to obtain pure silicate compounds. After purification, these compounds were found to be stable up to 1000 °C under an inert atmosphere (argon). The characterisation methods used to explore the synthesis and thermal stability included powder X-ray diffraction (PXRD), Fourier transform infrared (FTIR) and Raman spectroscopies, scanning electron microscopy (SEM) and thermogravimetric analysis (TGA).
ISSN:1477-9226
1477-9234
1477-9234
DOI:10.1039/d4dt01604a