Role of Ammonium Ions in the Formation of Ammonium Uranyl Peroxides and Uranyl Peroxo-oxalates

Role of Ammonium Ions in the Formation of Ammonium Uranyl Peroxides and Uranyl Peroxo-oxalates

The flexibility of the ammonium ion environment is suitable for inducing the formation of several uranyl peroxides and peroxo-oxalates. For a given concentration of uranium and various oxalate/uranium ratios, by varying the pH with ammonium hydroxide, crystals of eight compounds have been isolated a...

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Bibliographic Details
Published in:Crystal growth & design Vol. 16; no. 1; pp. 200 - 209
Main Authors: Blanchard, Florent, Ellart, Marine, Rivenet, Murielle, Vigier, Nicolas, Hablot, Isabelle, Morel, Bertrand, Grandjean, Stéphane, Abraham, Francis
Format: Journal Article
Language:English
Published: American Chemical Society 06-01-2016
Subjects:
Chemical Sciences
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Summary:The flexibility of the ammonium ion environment is suitable for inducing the formation of several uranyl peroxides and peroxo-oxalates. For a given concentration of uranium and various oxalate/uranium ratios, by varying the pH with ammonium hydroxide, crystals of eight compounds have been isolated and characterized by X-ray diffraction, in addition to the studtite (UO2)­(O2)·4H2O. All the compounds contain anionic uranyl polyhedra clusters with charge compensated by ammonium ions. Three are uranyl peroxides built from uranyl hexagonal bipyramids [(UO2)­(O2)3]4– or [(UO2)­(O2)2­(OH)2]4– sharing peroxide or dihydroxyl equatorial edges to form cage clusters [(UO2)28(O2)42]28– (U28) and [(UO2)44(O2)66]44– (U44) in 7 and 3 respectively, or crown-shaped cluster [(UO2)32­(O2(OH)2)52]40– (U32R) in 2. In these uranyl peroxides the pentagonal and hexagonal uranyl polyhedra rings are stabilized by ammonium ions. The other five compounds are uranyl peroxo-oxalates with various condensations of uranyl hexagonal bipyramids: (i) condensation of two [(UO2)­(O2)­(C2O4)2] bipyramids by peroxide ion sharing to form the dimer [(UO2)2(O2)­(C2O4)4]6– (U2Ox4) in 8, (ii) assembly of five [(UO2)­(O2)2­(C2O4)] bipyramids linked by sharing peroxide to form the [(UO2)5(O2)5­(C2O4)5]10– (U5Ox5) pentameric rings in 4 and 6, (iii) further condensation of 12 U5Ox5 rings through bis-bidentate oxalates to create the [(UO2)60­(O2)60(C2O4)30]60– (U60Ox30) nanosphere in 5, (iv) replacing an oxalate by two hydroxide ions in U5Ox5 rings and sharing of the OH–OH bridge between two pentamers to form the dimer of pentamers [(UO2)10­(O2)10­(OH)2­(C2O4)8]18– (U10Ox8) in 9. In the last four compounds, the ammonium ions stabilize the pentameric cycles. The ammonium ion has different effects, particularly in the case of pentamers, and thus provides access to a large panel of cluster sizes.
ISSN:1528-7483
1528-7505
DOI:10.1021/acs.cgd.5b01090