Ligand-based molecular recognition and dioxygen splitting: an endoepoxide ending

The phosphido complex RuCp*(PPh sub(2)CH&z.dbd; CHPPh sub(2))(PPh sub(2)) (1) was exposed to a number of small molecules and was found to recognize and activate molecular oxygen in an unprecedented fashion: the ruthenium species split O sub(2) in a ligand-based 4-electron reduction to produce an...

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Veröffentlicht in:	Dalton transactions : an international journal of inorganic chemistry 2014-02, Vol.43 (10), p.4137-4145
Hauptverfasser:	Sues, Peter E, bes, Matthew W, Lough, Alan J, Morris, Robert H
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Sprache:	eng
Schlagworte:	Analogue Computation Crossovers Ligands Recognition Ruthenium Splitting Trapping
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creator	Sues, Peter E bes, Matthew W Lough, Alan J Morris, Robert H
description	The phosphido complex RuCp(PPh sub(2)CH&z.dbd; CHPPh sub(2))(PPh sub(2)) (1) was exposed to a number of small molecules and was found to recognize and activate molecular oxygen in an unprecedented fashion: the ruthenium species split O sub(2) in a ligand-based 4-electron reduction to produce an endoepoxide, as well as a phosphinito ligand. Based on XRD data, VT NMR studies, cyclooctene trapping studies, and crossover experiments it was determined that the reaction proceeded through an intramolecular mechanism in which initial oxidation of the phosphido ligand generated an end-on peroxo intermediate. This mechanism was also supported by computational studies and electrochemical experiments. In contrast, an analogue of 1, RuCp(Ph sub(2)P(ortho-C sub(6)H sub(4))PPh sub(2) )(PPh sub(2)) (3), reacted in an intermolecular fashion to generate two phosphinito ligands.
doi_str_mv	10.1039/c3dt53495b
format	Article
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source	Royal Society Of Chemistry Journals 2008-; Alma/SFX Local Collection
subjects	Analogue Computation Crossovers Ligands Recognition Ruthenium Splitting Trapping
title	Ligand-based molecular recognition and dioxygen splitting: an endoepoxide ending
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