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Vallet V, Wahlgren U, Grenthe I. Probing the nature of chemical bonding in uranyl(VI) complexes with quantum chemical methods. J Phys Chem A. 2012;116(50):12373-80doi: 10.1021/jp3091123.
Vallet, V., Wahlgren, U., & Grenthe, I. (2012). Probing the nature of chemical bonding in uranyl(VI) complexes with quantum chemical methods. The journal of physical chemistry. A, 116(50), 12373-80. https://doi.org/10.1021/jp3091123
Vallet, Valérie, et al. "Probing the nature of chemical bonding in uranyl(VI) complexes with quantum chemical methods." The journal of physical chemistry. A vol. 116,50 (2012): 12373-80. doi: https://doi.org/10.1021/jp3091123
Vallet V, Wahlgren U, Grenthe I. Probing the nature of chemical bonding in uranyl(VI) complexes with quantum chemical methods. J Phys Chem A. 2012 Dec 20;116(50):12373-80. doi: 10.1021/jp3091123. Epub 2012 Nov 14. PMID: 23151258.
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J Phys Chem A. 2012 Dec 20;116(50):12373-80. doi: 10.1021/jp3091123. Epub 2012 Nov 14.

Probing the nature of chemical bonding in uranyl(VI) complexes with quantum chemical methods.

The journal of physical chemistry. A

Valérie Vallet, Ulf Wahlgren, Ingmar Grenthe

Affiliations

  1. Université Lille 1 (Sciences et Technologies), Laboratoire PhLAM, CNRS UMR 8523, Bât P5, F-59655 Villeneuve d'Ascq Cedex, France. [email protected]

PMID: 23151258 DOI: 10.1021/jp3091123

Abstract

To assess the nature of chemical bonds in uranyl(VI) complexes with Lewis base ligands, such as F(-), Cl(-), OH(-), CO(3)(2-), and O(2)(2-), we have used quantum chemical observables, such as the bond distances, the internal symmetric/asymmetric uranyl stretch frequencies, and the electron density with its topology analyzed using the quantum theory of atoms-in-molecules. This analysis confirms that complex formation induces a weakening of the uranium-axial oxygen bond, reflected by the longer U-O(yl) bond distance and reduced uranyl-stretching frequencies. The strength of the ligand-induced effect increases in the order H(2)O < Cl(-) < F(-) < OH(-) < CO(3)(2-) < O(2)(2-). In-depth analysis reveals that the trend across the series does not always reflect an increasing covalent character of the uranyl-ligand bond. By using a point-charge model for the uranyl tetra-fluoride and tetra-chloride complexes, we show that a significant part of the uranyl bond destabilization arises from purely electrostatic interactions, the remaining part corresponding either to charge-transfer from the negatively charged ligands to the uranyl unit or a covalent interaction. The charge-transfer and the covalent interaction are qualitatively different due to the absence of a charge build up in the uranyl-halide bond region in the latter case. In all the charged complexes, the uranyl-ligand bond is best described as an ionic interaction. However, there are covalent contributions in the very stable peroxide complex and, to some extent, also in the carbonate complex. This study demonstrates that it is possible to describe the nature of chemical bond by observables rather than by ad hoc quantities such as atomic populations or molecular orbitals.

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