An ideal separator of lithium-ion
battery (LIB) should have a zero
ionic resistance. Low ionic resistance (high ionic conductivity) will
greatly help to realize very fast ion diffusion and superhigh rate
capability of LIBs. The most effective technique to achieve low ionic
resistance of separator is to reduce its thickness or increase its
porosity. Paradoxically, the low thickness and high porosity will
inevitably decrease the mechanical strength of separators. Inspired
by the hierarchical structures of abalone shell, we demonstrate in
this work an ultrathin silica-anchored layered (PVdF/PE/PVdF) porous
fiber separator prepared via electrospinning. The separator displays
both ultrathin thickness (∼20 μm thick) and high mechanical
strength of ∼11.2 MPa, as well as high porosity, which results
in high electrolyte uptake (∼380%) and ionic conductivity (∼2.5
mS cm–1). When such thin separator was deployed
in a LiFePO4/Li cell, and the cell can deliver an initial
discharge capacity of 134.3 mA h g–1 at a high rate
of 10 C and maintain a capacity of 129.2 mA h g–1 after 300 charge–discharge cycles, showing excellent high-rate
performance. More interestingly, this study demonstrates a pathway
for the development of ultrathin and high-mechanical-strength electrospun
separators for high-rate Li-ion batteries.
A facile electrospinning and electrospraying synchronization technique is used to assemble 1D nanowires with 2D graphene sheets to build as 3D MnO/C@rGO composite thin film. The raw material MnO2powder was recovered from spent Zn/MnO2batteries.
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