Home

metallofullerenes

Metallofullerenes are a class of endohedral fullerenes in which a metal atom or a metal cluster is encapsulated inside a hollow carbon cage, typically C60, C70, or C82. They are distinguished from exohedral metal-doped fullerenes, where metal atoms reside outside the cage. Endohedral metallofullerenes include single-atom species M@C60 and M@C82 as well as clusterfullerenes such as M3N@C80, in which a metal nitride cluster resides inside the cage.

Electronic structure and properties are governed by charge transfer between the encapsulated metal and the carbon

Synthesis and isolation are typically achieved by high-temperature methods such as arc-discharge or laser ablation of

Notable examples include Sc3N@C80, Sc2@C80, La@C60, Y@C82, and Gd@C82. Applications discussed in the literature include fundamental

cage.
The
metal
often
donates
electrons
to
the
fullerene,
leading
to
a
filled
or
partially
filled
cage
electronic
shell
and
distinctive
redox
behavior.
The
resulting
complexes
can
exhibit
defined
spin
states
and
modified
optical
properties
relative
to
empty
cages.
The
presence
of
unpaired
electrons
in
the
metal
center
can
impart
paramagnetic
character,
making
metallofullerenes
of
interest
for
studies
in
molecular
magnetism,
spintronics,
and
quantum
information.
graphite
in
the
presence
of
a
suitable
metal
source.
The
reaction
mixture
contains
a
variety
of
fullerenes,
including
endohedral
species,
which
are
then
separated
by
chromatography,
especially
high-performance
liquid
chromatography,
to
yield
pure
metallofullerenes.
Purification
can
be
challenging,
and
yields
are
generally
low.
studies
of
electron
transfer
and
spin
states,
as
well
as
exploration
of
metallofullerenes
for
molecular
electronics
and
imaging,
though
practical
use
is
limited
by
synthesis
scale
and
stability
considerations.