![Author ORCID: We display the ORCID iD icon alongside authors names on our website to acknowledge that the ORCiD has been authenticated when entered by the user. To view the users ORCiD record click the icon. [opens in a new tab]](https://www.cambridge.org/engage/assets/public/coe/logo/orcid.png){kind=logo}
Abstract
Ceramic-rich solid-composite electrolytes exhibit ceramic-like ionic conductivity and enhanced mechanical property, making them promising candidates for market-relevant solid-state batteries. In-depth knowledge of the microstructure within the composite electrolytes for ideal performances and their correlation with the choice of materials and processing methods are not well-understood. Herein, we report a solution-cast, free-standing composite film comprised of well-integrated ceramic (Li3InCl¬6) and binder (Styrene-Ethylene-Butylene-Styrene, SEBS) phase, which simultaneously provides Li+ transport pathways and the required mechanical support. In the formation of this unique microstructure, we mark the mediator role of dibutyl ether – a low polarity solvent that forms a non-invasive polar-ionic interaction with the electronegative metal elements at the surface of Li3InCl¬6 particles to suspend and disperse Li3InCl6 particles in the dissolved SEBS matrix, facilitating phase integration. This weak interaction only occurs at chosen conditions; increased solvent-to-ceramic ratio and interaction time can induce Li3InCl6 decomposition. Our results correlate the electrochemical performance of a ceramic-rich Li3InCl6-SEBS composite electrolyte film with its microstructure; the latter was demonstrated to be potentially tunable by altering the molecular structure of the solvent and the parameters used in composite electrolyte synthesis procedures. This work provides materials structural-level insights that underpin the design principle of solution-cast solid composite electrolytes.
