Simple, Unambiguous Theoretical Approach to Oxidation State Determination via First-Principles Calculations

Simple, Unambiguous Theoretical Approach to Oxidation State Determination via First-Principles Calculations

We introduce a novel theoretical approach for determining oxidation states (OS) from quantum-mechanical calculations. For a transition-metal ion, for example, the metal–ligand orbital mixing contribution to the charge allocated to the ion is separated from that due to the actual occupation of the d-...

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Veröffentlicht in:Inorganic chemistry 2011-10, Vol.50 (20), p.10259-10267
Hauptverfasser: Sit, Patrick H.-L, Car, Roberto, Cohen, Morrel H, Selloni, Annabella
Format: Artikel
Sprache:eng
Schlagworte:
Ligands
Models, Chemical
Oxidation-Reduction
Quantum Theory
Transition Elements - chemistry
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Zusammenfassung:We introduce a novel theoretical approach for determining oxidation states (OS) from quantum-mechanical calculations. For a transition-metal ion, for example, the metal–ligand orbital mixing contribution to the charge allocated to the ion is separated from that due to the actual occupation of the d-orbitals from which OS can then be inferred. We report the application of this approach to different transition-metal systems: molecular complexes, ruthenium-dye molecules, ruthenium complexes with noninnocent ligands, and bulk semiconductors. The computations were carried out using density-functional theory with a Hubbard U correction. The oxidation states were determined without ambiguity.
ISSN:0020-1669
1520-510X
DOI:10.1021/ic2013107