Multivalent Ion Transport in Polymers via Metal-Ligand Coordination
ORAL
Abstract
Elucidating design rules for multivalent ion conducting polymers is critical for developing novel high-performance materials for electrochemical devices. Herein, we molecularly engineer multivalent ion conducting polymers based on metal-ligand interactions and illustrate that both segmental dynamics and ion coordination kinetics are essential for ion transport through polymers. We present a novel statistical copolymer, poly(ethylene oxide-stat-imidazole glycidyl ether) (i.e., PEO-stat-PIGE), that synergistically combines the structural hierarchy of PEO with the Lewis basicity of tethered imidazole ligands (x$_{\mathrm{IGE}}=$0.17) required to coordinate a series of transition metal salts containing bis(trifluoromethylsulfonyl)imide anions. Complexes of PEO-stat-PIGE with salts exhibit a nanostructure in which ion-enriched regions alternate with ion-deficient regions, and an ionic conductivity above 10$^{\mathrm{-5}}$ S/cm. Novel normalization schemes that account for ion solvation kinetics are presented to attain a universal scaling relationship for multivalent ion transport in polymers via metal-ligand coordination.
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Authors
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Gabriel Sanoja
University of California, Santa Barbara, Univ of California - Santa Barbara
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Nicole Schauser
Univ of California - Santa Barbara, University of California, Santa Barbara
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Christopher Evans
University of California, Santa Barbara
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Shubhaditya Majumdar
University of California, Santa Barbara
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Rachel Segalman
Univ of California - Santa Barbara, University of California - Santa Barbara, University of California, Santa Barbara