The reactivity toward dioxygen of two series of
dicobalt cofacial diporphyrins in solution in an aprotic
solvent is described. Some of these compounds are efficient
electrocatalysts for the four-electron reduction of
dioxygen
when adsorbed on a graphite electrode immersed in aqueous acid.
Their electrochemical and spectroscopic (UV−vis, EPR) behavior in solution shows that, contrary to what is observed
with cobalt monomers, the neutral
[PCoII CoIIP]
(1) (P stands for a porphyrin ring) form does not react with
dioxygen. Uniquely the one- and two-electron-oxidized
forms of the dimer,
[PCoII·CoIIP]+
(1
+
) and
[PCoII---CoIIP]2+
(1
2+
), respectively, reversibly
bind dioxygen, giving
two complexes, 2 and 3, at room temperature and
in the absence of a good axial ligand. The stability constants
of
the two O2 complexes have been measured
spectrophotometrically and/or electrochemically, and prove to be
remarkably
high. As a whole, the present O2 binding processes
appear unprecedented as basically different in many
respects
from the process classically described in the case of cobalt monomers.
Extended Hückel molecular orbital (EHMO)
calculations, based on the crystal structure of the
Co2FTF4 dimer in its uncomplexed form (Co−Co
distance 3.42
Å), show that, in the absence of very important deformations of its
structure, the only possible geometry for the
O2
complex of the two-electron-oxidized derivative
[PCo−O2−CoP]2+ (3) is the
μ-η2:η2-peroxo structure. The
calculated
corresponding electronic diagram affords a rationale for most of the
experimentally observed properties. Specifically,
the O2 complex of the one-electron-oxidized form
[PCo−O2
•−CoP]+
(2), the reduced form of complex 3, should
be
considered as a species in which the O2 moiety is further
reduced, at least partially, as compared to its peroxo
state
in 3, i.e., consequently in an oxidation state intermediate
between peroxo (−1) and oxo (−2). Preliminary
results
indicate that this species reacts with one proton, while the
two-electron-oxidized O2 complex 3 is resistant
to
protonation. The possible implications of these specific
properties of the dicobalt dimers in the four-electron
reduction
mechanism of O2 are discussed, and structural and
mechanistic similarities with bioinorganic dinuclear sites
appear
significant.
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