阳极
碳纤维
材料科学
杂原子
电池(电)
纳米技术
钠离子电池
化学工程
阴极
离子
扩散
电化学
兴奋剂
吸附
储能
机制(生物学)
结构稳定性
工作(物理)
容量损失
作者
Qian Long,Fangyuan Zhang,Jiayu Gina Qu,Songtao Li,Renfei Cheng,Yaning Zhao,Di Guo,Zhengwang Zhu,Haifeng Zhang
出处
期刊:Energy & environmental materials
[Wiley]
日期:2026-01-26
被引量:4
摘要
Hard carbon (HC) materials featuring well‐defined short‐range ordered architectures have emerged as promising anode materials for sodium‐ion batteries (SIBs). Nevertheless, due to the limited diffusion rate of sodium ions within the carbon structure, the rate capability of hard carbon at high current densities and long‐term cycling stability remains a challenge. Herein, an innovative nitrogen/sulfur co‐doping strategy is developed for loofah‐derived hard carbon (LHC‐N‐S), synergistically regulating the electron defect and spatial structure. The synergistic charge regulation is attributed to the introduction of N atoms for ion adsorption and the improvement of electron conductivity. The spatial structure regulation mainly comes from the S doping to optimize the layer spacing and pore size, which facilitates the rapid ion diffusion kinetics. The obtained LHC‐N‐S anodes maintain a high reversible specific capacity (317.5 mAh g −1 at 0.1 C) and ultralong lifespan (76% retention after 2000 cycles). Through the correlation analysis of the structural parameters and the Na + storage performance, the N/S co‐doping mechanism is further clarified. This work provides deep insights into the design of high‐performance biomass‐derived hard carbon anodes for SIBs by leveraging the synergistic charge and space regulation through heteroatom doping, paving the way for the development of durable and sustainable sodium‐ion battery technologies.
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