The reactivity of dicopper(I) complexes of the ligands
α,α‘-bis(4,7-diisopropyl-1,4,7-triazacyclononan-1-yl)-p-
and m-xylene (p- and
m-XYLiPr4) with dioxygen was examined by
spectroscopic and rapid stopped-flow kinetics
methods. Only bis(μ-oxo)dicopper(III) core
formation was observed with p-XYLiPr4, but both
(μ-η2:η2-peroxo)dicopper(II) and bis(μ-oxo)dicopper(III) species
were generated in the m-XYLiPr4 case, their
relative proportions
being dependent on the solvent, concentration of the dicopper(I)
precursor, and temperature. Subsequent
decomposition under conditions that favored bis(μ-oxo) core
formation resulted in oxidative N-dealkylation of
isopropyl groups, whereas μ-η2:η2-peroxo
decay led to the product resulting from hydroxylation of the
bridging
arene,
[(m-XYLiPr4-O)Cu2(μ-OH)](SbF6)2.
Evidence from kinetics studies, decomposition product analyses,
and
comparison to the chemistry exhibited by complexes of other substituted
1,4,7-triazacyclonane ligands support a
model for the oxygenation of the m-XYLiPr4
compound involving initial, essentially rate-limiting 1:1
Cu:O2 adduct
formation followed by partitioning between intra- and intermolecular
pathways. At low temperature and high
starting material concentrations, the latter route that yields
tetranuclear “dimer-of-dimer” species and/or higher
order oligomers with bis(μ-oxo) cores is favored, while at
higher temperatures and dilution, intramolecular reaction
predominates to afford a (peroxo)dicopper(II) species.
The course of the subsequent decompositions of these
oxygenated products correlates with their proposed formulations.
Thus, analysis of final products and kinetics
data, including with selectively deuterated compounds, showed that
N-dealkylation arises from the high-nuclearity
bis(μ-oxo) species and arene hydroxylation occurs upon decay of
the intramolecular peroxo complex. Geometric
rationales for the divergent oxygenation and decomposition reactions
supported by p- and m-XYLiPr4 are
proposed.
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