Si-containing
graphite-based composites are considered as promising high-capacity
anodes for lithium-ion batteries (LIBs). Here, a controllable and
scalable self-assembly strategy is developed to produce micro-nanostructured
graphite/Si/reduced graphene oxides composite (SGG). The self-assembly
procedure is realized by the hydrogen bond interaction between acylamino-modified
graphite and graphene oxides (GO); Si nanoparticles are in situ embedded
between graphite and GO sheets uniformly. This architecture is able
to overcome the incompatibility between Si nanoparticles and microsized
graphite. Accordingly, the as-prepared SGG anode (Si 8 wt %) delivers
a reversible Li-storage capacity of 572 mAh g–1 at
0.2 C, 502.2 mAh g–1 after 600 cycles at 0.8 C with
a retention of 92%, and a capacity retention of 64% even at 10 C.
The impressive electrochemical properties are ascribed to the stable
architecture and three-dimensional conductive network constructed
by graphite and graphene sheets, which can accommodate the huge volume
change of Si, keep the conductive contact and structural integrity,
and suppress side reactions with electrolyte. Additionally, the full-cell
(LiFePO4 cathode/SGG anode) delivers a specific capacity
of 550 mAh g–1 with a working potential beyond 3.0
V.