AI Article Synopsis
- The study reveals that while chalcogen-chalcogen bond activation by uranium complexes is common, O-O bond activation in organic peroxides is notably rare, spotlighting the activation of a specific peroxide via a uranium(III) complex.
- The reaction initiates with the cleavage of the O-O bond in 9,10-diphenylanthracene-9,10-endoperoxide, producing a stable uranium(V) bis-alkoxide complex through sequential one-electron oxidations.
- The mechanism involves the formation of a transient uranium-dioxo intermediate that subsequently rearranges to yield a stable uranyl trimer complex after release of an alkoxide ligand, emphasizing its significance in photochemical applications.
Article Abstract
The activation of chalcogen-chalcogen bonds using organometallic uranium complexes has been well documented for S-S, Se-Se, and Te-Te bonds. In stark contrast, reports concerning the ability of a uranium complex to activate the O-O bond of an organic peroxide are exceedingly rare. Herein, we describe the peroxide O-O bond cleavage of 9,10-diphenylanthracene-9,10-endoperoxide in nonaqueous media, mediated by a uranium(III) precursor [((ArO)N)U(dme)] to generate a stable uranium(V) bis-alkoxide complex, namely, [((ArO)N)U(DPAP)]. This reaction proceeds via an isolable, alkoxide-bridged diuranium(IV/IV) species, implying that the oxidative addition occurs in two sequential, single-electron oxidations of the metal center, including rebound of a terminal oxygen radical. This uranium(V) bis-alkoxide can then be reduced with KC to form a uranium(IV) complex, which upon exposure to UV light, in solution, releases 9,10-diphenylanthracene to generate a cyclic uranyl trimer through formal two-electron photooxidation. Analysis of the mechanism of this photochemical oxidation via density functional theory (DFT) calculations indicates that the formation of this uranyl trimer occurs through a fleeting uranium -dioxo intermediate. At room temperature, this -configured dioxo species rapidly isomerizes to a more stable configuration through the release of one of the alkoxide ligands from the complex, which then goes on to form the isolated uranyl trimer complex.
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