Sterically Stabilized End-On Superoxocopper(II) Complexes and Mechanistic Insights into Their Reactivity with O–H, N–H, and C–H Substrates

Abstract: Instability of end-on superoxocopper(II) complexes, with respect to conversion to the corresponding peroxobridged complexes, has largely constrained their study to very low temperatures (< -80 C). This limits their kinetic capacity to oxidize substrates. In response, we have developed a series of ligand systems bearing bulky aryl substituents that are primarily directed away from the metal centre, Ar3-TMPA (Ar = tpb, dpb, dtbpb), and used them to support [Cu I (Ar3-TMPA)(NCMe)] + copper(I) complexes. Solutions… Show more

“…For instance, proposed GO enzymatic cycles involve a H-atom transfer to a coordinating modified tyrosyl radical residue along with electron transfer to the Cu center as the active alcohol oxidizing steps, with O 2 serving to regenerate the oxidized active site . Conversely, studies of lytic polysaccharide monooxygenase (LPMO) active sites implicate a more direct substrate oxidizing role for O 2 -derived species such as Cu oxyl or Cu hydroxo species. , While several Cu–superoxo complexes have been shown to initiate the oxidation of moderately strong C–H and O–H bonds (BDEs of ∼70–83 k cal –1 mol –1 ), most model systems have not been able to mimic the reactivity of monooxygenase enzymes, which commonly activate C–H bonds with strengths of up to 87 k cal –1 mol –1 . − …”

Generation and Aerobic Oxidative Catalysis of a Cu(II) Superoxo Complex Supported by a Redox-Active Ligand

“…For instance, proposed GO enzymatic cycles involve a H-atom transfer to a coordinating modified tyrosyl radical residue along with electron transfer to the Cu center as the active alcohol oxidizing steps, with O 2 serving to regenerate the oxidized active site . Conversely, studies of lytic polysaccharide monooxygenase (LPMO) active sites implicate a more direct substrate oxidizing role for O 2 -derived species such as Cu oxyl or Cu hydroxo species. , While several Cu–superoxo complexes have been shown to initiate the oxidation of moderately strong C–H and O–H bonds (BDEs of ∼70–83 k cal –1 mol –1 ), most model systems have not been able to mimic the reactivity of monooxygenase enzymes, which commonly activate C–H bonds with strengths of up to 87 k cal –1 mol –1 . − …”

Generation and Aerobic Oxidative Catalysis of a Cu(II) Superoxo Complex Supported by a Redox-Active Ligand

“…2 Many efforts have been dedicated to the development of artificial Cu ligands able to generate and stabilize such metastable intermediates. Among them, the tris(2-pyridylmethyl)amine ( TPA ) ligand has been widely used as a scaffold for mimicking the first coordination sphere in the structural and functional models of copper, 3 but also iron, 4 mono-oxygenases. Interestingly, incorporating intramolecular H-bonding secondary spheres into the TPA ligand was reported as an efficient strategy to stabilize mononuclear hydroperoxo [(L)Cu II –OOH] + , 5 binuclear peroxodicopper [{(L)Cu II } 2 (O 2 2− )], 6 or end-on superoxo [(L)Cu II –O 2 ˙ − ] 7 copper–dioxygen intermediates.…”

A caged tris(2-pyridylmethyl)amine ligand equipped with a C_triazole–H hydrogen bonding cavity

“…A commonly invoked intermediate in enzymatic copper oxidases [1][2][3] and oxygenases 1,[4][5][6] is the end-on (η 1 ) cupric superoxide (Cu II -O2 •1-), which activates substrates through initial hydrogen atom transfer (HAT) reactions. This broad biological basis of reactivity has inspired the synthesis of molecular Cu II -O2 •1species, [7][8][9][10][11][12][13][14][15][16][17][18][19][20][21] but the study and use of these complexes is complicated by their instabilities with respect to formation of di(cupric)-μ-1,2-peroxides (Figure 1). The development of strategies for improving the lifetimes of Cu II -O2 •1complexes, while maintaining their oxidizing capacity, is expected to lead to the development of new catalysts based on the reactive superoxide moiety.…”

“…In the earliest studies, short-lived Cu II -O2 •1were detected by stopped-flow UV-vis spectroscopy under cryogenic conditions (-80 to -120 °C). 8,9,21 Strategies developed since then for increasing the lifetimes of these complexes have focused on i) increasing the steric bulk in the secondary coordination spheres, 12,13,15,16,18,20 ii) cathodically shifting the Cu I /Cu II redox potentials, 9 and iii) incorporating intramolecular hydrogen bonding residues into the secondary coordination spheres (Figure 1). 7,19 Molecular-scale electrostatic effects are gaining attention for their ability to meaningfully impact the chemistry of organic, transition metal, and enzymatic systems.…”

“…precluding the formation of di(cupric)-µ-peroxides (decreasing k2 in Figure 1), which has allowed for their observation at higher temperatures but not necessarily with higher binding affinities. 12,13,15,16,18,20 Alternatively, several studies have successfully imparted increased binding affinity of O2 (Keq in Figure 1). Derivatized TMPA ligands containing H-bonding moieties in the secondary coordination spheres were able to support cupric superoxides that were found to be persistent at -135 °C (t1/2 > 30 h).…”

Electrostatic Contributions to the Stability of an End-on Cupric Superoxide