交联增强了用于锂有机电池的四电子羰基吡啶鎓基聚合物的性能。

Cross-linking enhances the performance of four-electron carbonylpyridinium based polymers for lithium organic batteries.

作者信息

Li Hongyan, Chen Ling, Xing Fangfang, Miao Hongya, Zeng Jing, Zhang Sen, He Xiaoming

机构信息

Key Laboratory of Applied Surface and Colloid Chemistry (Ministry of Education), School of Chemistry and Chemical Engineering, Shaanxi Normal University Xi'an 710119 P.R. China

出版信息

Chem Sci. 2024 Aug 9;15(35):14399-405. doi: 10.1039/d4sc04179h.

DOI:10.1039/d4sc04179h

PMID:39165730

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11331337/

Abstract

Design and integration of multiple redox-active organic scaffolds into tailored polymer structures to enhance the specific capacity and cycling life is a long-term research goal. Inspired by nature, we designed and incorporated a 4-electron accepting dicarbonylpyridinium redox motif into linear (DBMP) and cross-linked polymer (TBMP) structures. Benefiting from the suppressed solubility and higher electronic conductivity, the cross-linked TBMP based electrode exhibits improved cycling stability and higher specific capacity than the linear counterpart. After 4000 cycles at 1 A g, TBMP can maintain a high capacity of 252 mA h g, surpassing the performance of many reported organic cathodes. The structural evolution and reaction kinetics during charge and discharge have been investigated in detail. This study demonstrates that cross-linking is an effective strategy to push the bio-derived carbonylpyridinium materials for high performance LOBs.

摘要

将多种氧化还原活性有机支架设计并整合到定制的聚合物结构中以提高比容量和循环寿命是一个长期的研究目标。受自然启发，我们设计并将一个接受4个电子的二羰基吡啶鎓氧化还原基序纳入线性（DBMP）和交联聚合物（TBMP）结构中。得益于溶解性的抑制和更高的电子导电性，基于交联TBMP的电极表现出比线性对应物更好的循环稳定性和更高的比容量。在1 A g下循环4000次后，TBMP可保持252 mA h g的高容量，超过了许多已报道的有机阴极的性能。已详细研究了充放电过程中的结构演变和反应动力学。这项研究表明交联是推动生物衍生的羰基吡啶鎓材料用于高性能锂有机电池的有效策略。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/8d7e/11389428/ec1d70642feb/d4sc04179h-f1.jpg

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交联增强了用于锂有机电池的四电子羰基吡啶鎓基聚合物的性能。

Cross-linking enhances the performance of four-electron carbonylpyridinium based polymers for lithium organic batteries.

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