Synthesis and Morphological Control of UO<sub>2</sub>F<sub>2</sub>Particulates

Jang, Harry; Louis–Jean, James; Poineau, Frédéric

doi:10.1021/acsomega.3c01999

Cited by 3 publications

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“…UO 2 F 2 ms has already been reported and was prepared from the reaction of UO 3 ms with SBF. 29 Here, we report the formation of UO 2 F 2 ms by two other routes: the reactions of U 3 O 8 ms with ABF and SBF.…”

Section: ■ Results and Discussionmentioning

confidence: 87%

“…For actinides, one simple chemical transformation is the replacement of O by F atoms in oxide materials using a solid–gas reaction . Recently, we reported one such approach and prepared uranyl difluoride microspheres from the reaction of UO 3 ms and HF (g) produced from the decomposition of silver bifluoride (SBF) . The motivation for studying uranyl difluoride is that the material is relevant to nuclear and safeguard applications (e.g., as an intermediate for UF 6 and UO 2 conversion). − Also, fluorinated U materials (UO 2 F 2 , UF 4 ) exhibit photoluminescent properties , that are studied to improve radiation detection technology, such as the detection of leaking UF 6 cylinders and sensitive low-dose measurements …”

Section: Introductionmentioning

confidence: 99%

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Tailoring Triuranium Octoxide into Multidimensional Uranyl Fluoride Micromaterials

Jang,

Poineau

2024

ACS Omega

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Uranium microstructured materials with controlled size and shape are relevant to the nuclear industry and have found applications as targets for medical isotope production, fuels for nuclear reactors, standards for nuclear forensics, and energy sources for space exploration. Until now, most studies at the microscale have focused on uranium microspheres (oxides, nitrides, carbides, and fluorides), while micromaterials of uranium halides, carbides, and pnictides with other morphologies are largely unknown. A promising method to shape the morphology of uranium micromaterials is the replacement of O by F atoms in oxide materials using a solid−gas reaction. Here, with the aim to elaborate unexplored uranium fluoride micromaterials, the fluorination of uranium oxide (U 3 O 8 and UO 2 ) microspheres (ms), microrods (mr), and microplates (mp) in an autoclave at 250 °C with HF (g) (produced from the thermal decomposition of silver bifluoride (SBF)) and with ammonium bifluoride (ABF) was evaluated. We show that the reactions between U 3 O 8 mr and U 3 O 8 mp and SBF provided the most efficient way to elaborate mr and mp UO 2 F 2 micromaterials in a high yield (∼90%). The resulting UO 2 F 2 mr (length: 3−20 μm) and UO 2 F 2 mp (width: 1−7.5 μm) exhibited a well-defined geometry that was identical to that of the U 3 O 8 precursors. Agglomerated (NH 4 ) 3 UO 2 F 5 and UO 2 F 2 ms (2−3.5 μm) were prepared from the reaction of U 3 O 8 ms with ABF. It is noted that the reaction of UO 2 ms with SBF and ABF did not provide any uranium fluoride micromaterials. The successful preparation of uranium fluoride microstructures (ms, mr, and mp) developed here opens the way to novel actinide fluoride micromaterials.

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Section: ■ Results and Discussionmentioning

confidence: 87%