Controlled Deprotection and Reorganization of Uranyl Oxo Groups in a Binuclear Macrocyclic Environment

Jones, Guy M.; Arnold, Polly L.; Love, Jason B.

doi:10.1002/ange.201207609

Cited by 6 publications

(2 citation statements)

References 44 publications

(21 reference statements)

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“…In contrast, alkali uranyl-peroxide formation from the oxides features highly exothermic enthalpies of formation from the oxides plus oxygen (DH o f,ox ); [4a] and these phases remain thermodynamically stable to spontaneous decomposition with the evolution of oxygen, even in the absence of excess peroxide in the aqueous solution. Thus, it is even thermodynamically favorable to form them from UO 2 in the absence of peroxide; [5] rather atmospheric oxygen can be reduced to peroxide, whereas U 4 + is oxidized to U 6 + , although the details of such a process have not been elucidated.…”

Section: Introductionmentioning

confidence: 99%

The Energy Landscape of Uranyl–Peroxide Species

Tiferet

Gil

et al. 2014

Chemistry A European J

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Nanoscale uranyl peroxide clusters containing UO2(2+) groups bonded through peroxide bridges to form polynuclear molecular species (polyoxometalates) exist both in solution and in the solid state. There is an extensive family of clusters containing 28 uranium atoms (U28 clusters), with an encapsulated anion in the center, for example, [UO2(O2)(3-x)(OH)(x)(4-)], [Nb(O2)4(3-)], or [Ta(O2)4(3-)]. The negative charge of these clusters is balanced by alkali ions, both encapsulated, and located exterior to the cluster. The present study reports measurement of enthalpy of formation for two such U28 compounds, one of which is uranyl centered and the other is peroxotantalate centered. The [(Ta(O2)4]-centered U28 capsule is energetically more stable than the [(UO2)(O2)3]-centered capsule. These data, along with our prior studies on other uranyl-peroxide solids, are used to explore the energy landscape and define thermochemical trends in alkali-uranyl-peroxide systems. It was suggested that the energetic role of charge-balancing alkali ions and their electrostatic interactions with the negatively charged uranyl-peroxide species is the dominant factor in defining energetic stability. These experimental data were supported by DFT calculations, which agree that the [(Ta(O2)4]-centered U28 capsule is more stable than the uranyl-centered capsule. Moreover, the relative stability is controlled by the interactions of the encapsulated alkalis with the encapsulated anion. Thus, the role of alkali-anion interactions was shown to be important at all length scales of uranyl-peroxide species: in both comparing clusters to clusters; and clusters to monomers or extended solids.

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Section: Introductionmentioning

confidence: 99%

The Energy Landscape of Uranyl–Peroxide Species

Tiferet

Gil

et al. 2014

Chemistry A European J

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“…Usually, the linear uranyl cation is equatorially coordinated by 4 to 6 ligands. [17][18][19][20][21][22][23] A great number of donors [19][20][21][22][23][24][25][26][27][28][29][30][31][32] such as nitrogen (pyridine, polypyridine, porphyrin, expanded porphyrin and calixpyrroles), oxygen (THF) and halogen have been attempted for uranyl complexation. These experimentally synthesized complexes as well as their characterization and relevant theoretical computations have provided an insight into their electronic structures and physicochemical properties [9][10][11]13].…”

Section: Introductionmentioning

confidence: 99%

Tuning electronic structures of uranyl fluorides via increasing equatorial pyridyl number and extending pyridyl conjugation

Wang

Bai

et al. 2015

Computational and Theoretical Chemistry

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Axially Symmetric U−O−Ln‐ and U−O−U‐Containing Molecules from the Control of Uranyl Reduction with Simple f‐Block Halides

et al. 2017

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The reduction of U VI uranyl halides or amides with simple Ln II or U III salts forms highly symmetric, linear,o xobridged trinuclear U V /Ln III /U V ,Ln III /U IV /Ln III ,and U IV /U IV /U IV complexes or linear Ln III /U V polymers depending on the stoichiometry and solvent. The reactions can be tuned to give the products of one-or two-electron uranyl reduction. The reactivity and magnetism of these compounds are discussed in the context of using aseries of strongly oxo-coupled homo-and heterometallic poly(f-block) chains to better understand fundamental electronic structure in the f-block.

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Controlled Deprotection and Reorganization of Uranyl Oxo Groups in a Binuclear Macrocyclic Environment

Cited by 6 publications

References 44 publications

The Energy Landscape of Uranyl–Peroxide Species

The Energy Landscape of Uranyl–Peroxide Species

Tuning electronic structures of uranyl fluorides via increasing equatorial pyridyl number and extending pyridyl conjugation

Axially Symmetric U−O−Ln‐ and U−O−U‐Containing Molecules from the Control of Uranyl Reduction with Simple f‐Block Halides

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