Author:
Tian Ye,Wang Kaiyu,Yuan Yufei,Chen Huanhuan,Bang Ki-Taek,Tao Ran,Wang Rui,Lan Yaozhong,Kim Yoonseob
Abstract
Abstract
Owing to their well-defined crystalline pore structures and ordered functional ionic groups along the skeleton, ionic covalent organic frameworks (iCOFs) exhibit excellent performance and have significant potential for use in energy storage and conversion devices. Herein, we for the first time developed cationic phosphonium COFs with high hydroxide conduction even with low ion exchange capacity (IEC). Specifically, COFs containing quaternary phosphoniums groups as excellent ion transport moieties were synthesized. Moreover, we fabricated freestanding phosphonium membranes through a vapor-assisted method, which exhibited high hydroxide conductivity of 126 mS cm–1 at 80°C with a minimal IEC of 1.17 mmol g–1. Overall, in addition to investigating a novel cationic functional group, we demonstrated a freestanding film formation method of COF-based materials. The findings can provide a solid foundation for advancing the field of iCOFs to ion transport and promoting electrochemical applications.
Publisher
Research Square Platform LLC
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