posted on 2022-12-19, 19:11authored byMatthew
J. Lueckheide, Mehmed Z. Ertem, Michael A. Michon, Pawel Chmielniak, Jerome R. Robinson
Metal peroxides are key species involved in a range of
critical
biological and synthetic processes. Rare-earth (group III and the
lanthanides; Sc, Y, La–Lu) peroxides have been implicated as
reactive intermediates in catalysis; however, reactivity studies of
isolated, structurally characterized rare-earth peroxides have been
limited. Herein, we report the peroxide-selective (93–99% O22‑) reduction of dioxygen (O2) at redox-inactive rare-earth triflates in methanol using a mild
metallocene reductant, decamethylferrocene (Fc*). The first molecular
praseodymium peroxide ([PrIII2(O22–)(18C6)2(EG)2][OTf]4; 18C6 = 18-crown-6, EG = ethylene glycol, –OTf = –O3SCF3; 2-Pr) was isolated and characterized by single-crystal X-ray diffraction,
Raman spectroscopy, and NMR spectroscopy. 2-Pr displays
high thermal stability (120 °C, 50 mTorr), is protonated by mild
organic acids [pKa1(MeOH) = 5.09 ±
0.23], and engages in electrophilic (e.g., oxygen atom transfer) and
nucleophilic (e.g., phosphate-ester cleavage) reactivity. Our mechanistic
studies reveal that the rate of oxygen reduction is dictated by metal-ion
accessibility, rather than Lewis acidity, and suggest new opportunities
for differentiated reactivity of redox-inactive metal ions by leveraging
weak metal–ligand binding events preceding electron transfer.