Revisiting formal copper(III) complexes : bridging perspectives with quasi-d^10 configurations

The formal Cu(III) complex [Cu(CF3)(4)](1-) has often served as a paradigmatic example of challenging oxidation state assignment - with many reports proposing conflicting descriptions. Here we report a computational analysis of this compound, employing Energy Decomposition Analysis and Intrinsic Bon...

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Hauptverfasser:	Leach, Isaac F, Havenith, Remco, Klein, Johannes E. M. N
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Sprache:	eng
Schlagworte:	Bonding theory CHARGE Chemistry Computational chemistry COORDINATION DISSOCIATIVE ADSORPTION Inorganic Chemistry Oxidation states OXIDATION-STATE Population analysis QUANTUM TRANSITION-METALS
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creator	Leach, Isaac F Havenith, Remco Klein, Johannes E. M. N
description	The formal Cu(III) complex [Cu(CF3)(4)](1-) has often served as a paradigmatic example of challenging oxidation state assignment - with many reports proposing conflicting descriptions. Here we report a computational analysis of this compound, employing Energy Decomposition Analysis and Intrinsic Bond Orbital Analysis. We present a quasi-d(10) perspective of the metal centre, resulting from ambiguities in d-electron counting. The implications for describing reactions which undergo oxidation state changes, such as the formal reductive elimination from the analogous [Cu(CF3)(3)(CH2Ph)](1-) complex (Paeth et al. J. Am. Chem. Soc. 2019, 141, 3153), are probed. Electron flow analysis finds that the changes in electronic structure may be understood as a quasi-d(10) to d(10) transition at the metal centre, rendering this process essentially redox neutral. This is reminiscent of a previously studied formal Ni(IV) complex (Steen et al. Angew. Chem. Int. Ed. 2019, 58, 13133-13139), and indicates that our description of electronic structure has implications for the understanding of elementary organometallic reaction steps.
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M. N</creator><creatorcontrib>Leach, Isaac F ; Havenith, Remco ; Klein, Johannes E. M. N</creatorcontrib><description>The formal Cu(III) complex [Cu(CF3)(4)](1-) has often served as a paradigmatic example of challenging oxidation state assignment - with many reports proposing conflicting descriptions. Here we report a computational analysis of this compound, employing Energy Decomposition Analysis and Intrinsic Bond Orbital Analysis. We present a quasi-d(10) perspective of the metal centre, resulting from ambiguities in d-electron counting. The implications for describing reactions which undergo oxidation state changes, such as the formal reductive elimination from the analogous [Cu(CF3)(3)(CH2Ph)](1-) complex (Paeth et al. J. Am. Chem. Soc. 2019, 141, 3153), are probed. Electron flow analysis finds that the changes in electronic structure may be understood as a quasi-d(10) to d(10) transition at the metal centre, rendering this process essentially redox neutral. 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source	Ghent University Academic Bibliography; Wiley Online Library All Journals
subjects	Bonding theory CHARGE Chemistry Computational chemistry COORDINATION DISSOCIATIVE ADSORPTION Inorganic Chemistry Oxidation states OXIDATION-STATE Population analysis QUANTUM TRANSITION-METALS
title	Revisiting formal copper(III) complexes : bridging perspectives with quasi-d^10 configurations
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