Carbonyl oxygen atoms are the primary active sites to
solvate Li
salts that provide a migration site for Li ions conducting in a polycarbonate-based
polymer electrolyte. We here exploit the conductivity of the polycarbonate
electrolyte by tuning the segmental motion of the structural unit
with carbonyl oxygen atoms, while its correlation to the mechanical
and electrochemical stability of the electrolyte is also discussed.
Two linear alkenyl carbonate monomers are designed by molecular engineering
to combine methyl acrylate (MA) and the commonly used ethylene carbonate
(EC), w/o dimethyl carbonate (DMC) in the structure. The integration
of the DMC structural unit in the side chain of the in situ constructed
polymer (p-MDE) releases the free motion of the terminal EC units,
which leads to a lower glass-transition temperature and higher ionic
conductivity. While pure polycarbonates are normally fragile with
high Young’s modulus, such a prolonged side chain also manipulates
the flexibility of the polymer to provide a mechanical stable interface
for Li-metal anode. Stable long-term cycling performance is achieved
at room temperature for both LiFePO4 and LiCoO2 electrodes based on the p-MDE electrolyte incorporated with a solid
plasticizer.