Spinning Dope Modulation Via pH-Triggered Multiscale Sheet-Wire Linkages for Constructing Strong Ti3C2TX MXene Fibers with High Volumetric Capacitance

Luming Pan, Huifang Wang, Jingbo Zhou, Henghan Dai, Hai Xu, Yang Guo, Tianmin Cheng, Leang Yin, Tian Zhang, Yuzhen Wang, Jinyuan Zhou, Gengzhi Sun

科研成果: 期刊稿件文章同行评审

摘要

Due to their ultrahigh volumetric capacitance, metallic conductivity, and excellent mechanical properties, Ti3C2TX MXene nanosheets are considered promising building blocks for the construction of advanced fibers toward the practical applications of fibriform supercapacitors (FSCs) that emerge as an important power supplying system for wearable electronics. However, because of the incompatible interfacial and microstructural design concepts, synergistic improvement in output capacitance and tensile strength remains a critical challenge for Ti3C2TX fibers. Herein, a versatile pH-triggered strategy is presented for modulating Ti3C2TX spinning dope toward the construction of high-performance MXene fibers with simultaneous enhancement in electrochemical capacitance and mechanical strength. Carboxylated cellulose nanofibers (CNF-C) are selected as the additives in Ti3C2TX stock and multiscale sheet-wire linkages are arbitrarily formed via nucleophilic substitution and dehydration reactions by adjusting the pH value. The nematic LC behavior and the spinnability of Ti3C2TX dope are significantly improved with the good ordering of MXene nanosheets. Impressively, the optimized MCC4 fiber achieves an electrical conductivity of 3007 S cm−1, a specific capacitance of 1253 F cm−3 and a tensile strength of 258 MPa. The solid-state FSCs assembled from MCC4 fibers exhibit a remarkable energy density of 22.78 mWh cm−3 together with excellent charge/discharge reliability and outstanding robustness.

源语言英语
期刊Advanced Functional Materials
DOI
出版状态已接受/待刊 - 2025

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