Lithium-ion batteries (LIB), as pow

Lithium-ion batteries (LIB), as power sources for mobile
communication devices, portable electronic devices, and
electrical/hybrid vehicles, have attracted special attention in
the scientific and industrial fields due to their high electromotive
force and high energy density. For an anode material
in LIB, graphite is usually employed as a standard electrode
because it can be reversibly charged and discharged under
intercalation potentials with reasonable specific capacity.1,2
However, to meet the increasing demand for batteries with
higher energy density, much research attempt has been made
to explore new electrode materials or design novel nanostructures
of electrode materials.3-7 Especially, among the
carbonaceous materials, graphene-based materials could be
one of the promising alternatives as an anode in LIB because
these materials have superior electrical conductivities than
graphitic carbon, high surface area of over 2600 m2/g,
chemical tolerance, and a broad electrochemical window that
would be very advantageous for application in energy
technologies.8-12 Recently, we are quite successful in the
controlled reassembling of exfoliated graphene nanosheets
(GNS) with carbon nanotubes and fullerenes.13 According
to our previous experiments, the obtained GNS families show
very large reversible capacity, which can be attributed to
the increased basal spacing of GNS in comparison with that
of graphite. Such an exfoliation-reassembling method can
be extended to fabricate a new hybrid electrode material that
is composed of GNS and transition metal oxide nanoparticles.
For example, tin oxide (SnO2) could be a good substitute
for the carbon anode in LIB because its high theoretical Li+
storage capacity of 782 mAh/g is much larger than that (372
mAh/g) of graphite. However, similar to the other lithium
reactive electrode materials, tin oxide shows very large
volume change of about 300% during charge/discharge
process, which causes crumbling and cracking of electrode,
leading to electrical disconnection from current collectors.
14-16 Therefore, most of tin oxide electrode materials
suffer from the rapid fading of capacity. Although several
attempts have been made to prepare new nanostructures
based on the tin oxide,17,18 most efforts so far proved not to
be very successful in enhancing the cyclability of tin oxide
based electrodes.
To circumvent these problems, we have attempted to
reassemble graphene nanosheets (GNS) in the presence of