Effects of crosslinking density and Lewis acidic sites on conductivity and viscoelasticity of dynamic network electrolytes
Brian B. Jing, Patricia Mata, Qiujie Zhao, Christopher M. Evans
Abstract
Abstract Polymers are promising materials for replacing organic liquids as electrolytes, and network architectures allow for the modulus to be tuned pseudo‐independently of conductivity. When the crosslinks are dynamic bonds, they offer the additional benefits of recyclability and self‐healing in response to damage. Dynamic network electrolytes (DNEs) comprised of precise linker lengths of 2, 3, or 4 repeat units of ethylene oxide and boronic ester junctions were prepared to investigate the roles of dense networks and bond exchange on conductivity and rheological properties. A range of salt concentrations were probed, and longer linker lengths led to consistently higher conductivities even after accounting for difference in the glass transition. In contrast, non‐monotonic trends are observed in the salt dependence of viscosity as a function of linker length. The interaction of anions from the salt with boron leads to a drop in the viscosity, and at a critical salt content the networks no longer form a percolated network. From the bulk viscosity, a Walden Plot shows a transition from superionic to subionic behavior with added salt. These structure–property relationships offer key valuable insights for designing sustainable electrolytes.