Please use this identifier to cite or link to this item: http://dr.iiserpune.ac.in:8080/xmlui/handle/123456789/3266
Title: Predicting the redox properties of uranyl complexes using electronic structure calculations
Authors: Khungar, Bharti
Roy, Ankita
KUMAR, ANAND
Sadhu, Biswajit
Sundararajan, Mahesh
Dept. of Chemistry
Keywords: Predicting the redox properties
Electronic structure calculations
Plethora of chemical reactions
ab initio
Density functional theory
Redox properties uranyl
2017
Issue Date: Jun-2017
Publisher: Wiley
Citation: International Journal of Quantum Chemistry, 117(12), e25370.
Abstract: A plethora of chemical reactions is redox driven processes. The conversion of toxic and highly soluble U(VI) complexes to nontoxic and insoluble U(IV) form are carried out through proton coupled electron transfer by iron containing cytochromes and mineral surfaces such as machinawite. This redox process takes place through the formation of U(V) species which is unstable and immediately undergo the disproportionation reaction. Thus, theoretical methods are extremely useful to understand the reduction process of U(VI) to U(V) species. We here have carried out the structures and reduction properties of several U(VI) to U(V) complexes using a variety of electronic structure methods. Due to the lack of experimental ionization energies for uranyl (UO2(V)‐UO2(VI)) couple, we have benchmarked the current and popularly used density functionals and cost effective ab initio methods against the experimental electron detachment energies of [UO2F4]1‐/2‐ and [UO2Cl4]1‐/2‐. We find that electron detachment energy of U(VI) predicted by RI‐MP2 level on the BP86 geometries correlate nicely with the experimental and CCSD(T) data. Based on our benchmark studies, we have predicted the structures and electron detachment energies of U(V) to U(VI) species for a series of uranium complexes at the RI‐MP2//BP86 level which are experimentally inaccessible till date. We find that the redox active molecular orbital is ligand centered for the oxidation of U(VI) species, where it is metal centered (primarily f‐orbital) for the oxidation of U(V) species. Finally, we have also calculated the detachment energies of a known uranyl [UO2]1+ complex whose X‐ray crystal structures of both oxidation states are available. The large bulky nature of the ligand stabilizing the uncommon U(V) species which cannot be routinely studied by present day CCSD(T) methods as the system size are more than 20–30 atoms. The success of our efficient computational strategy can be experimentally verified in the near future for the complex as the structures are stable in gas phase which can undergo oxidation.
URI: http://dr.iiserpune.ac.in:8080/xmlui/handle/123456789/3266
https://doi.org/10.1002/qua.25370
ISSN: 0020-7608
1097-461X
Appears in Collections:JOURNAL ARTICLES

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