金属@碳纳米片异质界面的协同工程用于双功能电磁波吸收与电化学储能

魏祺 仇亚茹 杨腾飞 蒋艺玲 朱韶涵 周杰 刘聪聪 侯文杰 王越 刘冬

引用本文: 魏祺, 仇亚茹, 杨腾飞, 蒋艺玲, 朱韶涵, 周杰, 刘聪聪, 侯文杰, 王越, 刘冬. 金属@碳纳米片异质界面的协同工程用于双功能电磁波吸收与电化学储能[J]. 物理化学学报, 2026, 42(9): 100320. doi: 10.1016/j.actphy.2026.100320 shu
Citation:  Qi Wei, Yaru Qiu, Tengfei Yang, Yiling Jiang, Shaohan Zhu, Jie Zhou, Congcong Liu, Wenjie Hou, Yue Wang, Dong Liu. Synergistic engineering of heterointerfaces in metal@carbon nanosheets for bifunctional electromagnetic wave absorption and electrochemical energy storage[J]. Acta Physico-Chimica Sinica, 2026, 42(9): 100320. doi: 10.1016/j.actphy.2026.100320 shu

金属@碳纳米片异质界面的协同工程用于双功能电磁波吸收与电化学储能

    通讯作者: Email: tjuzhoujie@163.com (周杰); byhhwj@163.com (侯文杰); liu_dong@sdut.edu.cn (刘冬)
摘要: 无线通信与电子设备的普及加剧了电磁波污染与高性能储能需求的双重挑战。为解决这些问题,我们开发了一种简易策略制备金属(铜或钴)修饰的软碳多孔纳米片复合材料,该材料具有原位分散金属纳米颗粒的多级孔纳米片结构。系统表征证实了晶态铜相和钴相在碳基体中的成功复合。其中SC-N/Co复合材料展现出卓越的多功能性能:作为电磁波吸收体时,在1.5 mm的薄层厚度下可实现-39.10 dB的强反射损耗与6.16 GHz的宽频带吸收;作为锂离子电池负极时,则表现出高可逆容量、优异倍率性能及在1.0 A g-1电流密度下循环1000次后仍保持~325 mA h g-1的长周期稳定性。这种卓越性能源于界面极化增强、阻抗匹配优化及电荷传输动力学改善等多重协同效应。本研究为设计兼具电磁波调控与高效储能双功能的碳-金属复合材料提供了新思路。

English

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  • 发布日期:  2026-09-15
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