C. Kang et Fc. Anson, EFFECTS OF COORDINATION TO A MACROCYCLIC COBALT COMPLEX ON THE ELECTROCHEMISTRY OF DIOXYGEN, SUPEROXIDE, AND HYDROPEROXIDE, Inorganic chemistry, 34(10), 1995, pp. 2771-2780
The reduction of O-2 as catalyzed by the complex of Co(II) with the ma
crocyclic ligand ,12,14,14-hexamethyl-1,4,8,11-tetraazacyclotetrade (h
mc) was examined using electrochemical techniques. The metastable (hmc
)CoOO2+ complex is an intermediate in the catalytic cycle. It is in ra
pid equilibrium with Oz and (hmcCo2+. The (hmc)CoOO2+ complex is a str
ong oxidant that is rapidly reduced to (hmc)CoOOH2+ at the potential w
here (hmcCo3+ is reduced to (hmcCo2+ (0.38 V vs NHE). At more negative
potentials (0.07 V) (hmc)CoOOH2+ is reduced irreversibly to H2O2 and
(hmcCo2+ and the catalytic electroreduction of Oz to H2O2 ensues. The
electroreduction of (coordinated) Oz to (coordinated) OOH- at potentia
ls where uncoordinated O-2 is not reducible is attributed to stabiliza
tion of the reduced ligand by the cobalt center to which it is coordin
ated. Digital simulation was employed to obtain an estimate (0.99 V vs
NHE) for the formal potential of the (hmc)CoOO2+/(hmc)CoOOH2+ couple
at pH 1. The OOH- Ligand coordinated to (hmcCo3+ is electrooxidized to
O-2 near 0.9 V vs NHE, but uncoordinated H2O2 is unreactive at this p
otential. The affinities of OO- and OOH- for (hmcCo3+ are comparable d
espite their highly disparate Bronsted basicities. Greater stabilizati
on of the (hmc)Co00(2+) than of the (hmc)CoOOH2+ complex by LMCT is su
ggested to account for this result.