Fast O₂ binding at dicopper complexes containing Schiff-base dinucleating ligands

A new family of dicopper(I) complexes [Cu^I₂ ^RL](X)₂ (R = H, 1X, R = ^tBu, 2X and R = NO ₂, 3X, X = CF₃SO₃, ClO₄, SbF ₆, or BArF, BArF = [B{3,5-(CF₃)₂C ₆H₃}₄]^-), where ^RL is a Schiff-base ligand containing two tridentate binding sites linked by a xylyl spacer, has been prepared and characterized, and its reaction with O₂ has been studied. The complexes were designed with the aim of reproducing structural aspects of the active site of type 3 dicopper proteins; they contain two three-coordinate copper sites and a rather flexible podand ligand backbone. The solid-state structures of 1ClO₄, 2CF₃SO₃, 2ClO₄, and 3BArF·CH₃CN have been established by single-crystal X-ray diffraction analysis. 1ClO₄ adopts a polymeric structure in the solid state while 2CF₃SO₃, 2ClO ₄, and 3BArF-CH₃CN are monomeric. The complexes have been studied in solution by means of ¹H and ¹⁹F NMR spectroscopy, which put forward the presence of dynamic processes. 1-3BArF and 1-3CF₃SO₃ in acetone react rapidly with O₂ to generate metaestable [Cu^III2(μ-O)₂(^RL)] ²⁺ 1-3(O₂) and [Cu^III₂(μ-O) ₂(CF₃SO₃)(^RL)]⁺ 1-3(O₂)(CF₃SO₃) species, respectively, that have been characterized by UV-vis spectroscopy and resonance Raman analysis. Instead, reaction of 1-3BArF with O₂ in CH₂Cl₂ results in intermolecular O₂ binding. DFT methods have been used to study the chemical identities and structural parameters of the O₂ adducts, and the relative stability of the Cu^III₂(μ-O) ₂ form with respect to the Cu^II₂(μ- η²:η²-O₂) isomer. The reaction of 1X, X = CF₃SO₃ and BArF, with O₂ in acetone has been studied by stopped-flow UV-vis exhibiting an unexpected very fast reaction rate (k = 3.82(4) ± 10³ M^-1 s^-1, ΔH‡ = 4.9 ± 0.5 kJ·mol^-1, ΔS‡ = -148 ± 5 J·K^-1·mol^-1), nearly 3 orders of magnitude faster than in the parent [Cu^I ₂(m-XYL^MeAN)]²⁺. Thermal decomposition of 1-3(O₂) does not result in aromatic hydroxylation. The mechanism and kinetics of O2 binding to 1X (X = CF₃SO₃ and BArF) are discussed and compared with those associated with selected examples of reported models of O₂-processing copper proteins. A synergistic role of the copper ions in O₂ binding and activation is clearly established from this analysis.