材料科学
化学工程
纳米尺度
聚合
纳米壳
单体
胶束
碳纤维
收缩率
扩散
纳米颗粒
纳米技术
球体
压力(语言学)
聚合物
体积热力学
阳极
肿胀 的
工作(物理)
纳米反应器
壳体(结构)
吸附
氧化物
各向同性
应力松弛
复合材料
多孔性
作者
Jiaying Yang,Rong Zhuang,Kejie Wang,D. Liu,Yue Ma,JianGan Wang,Hongqiang Wang,Fei Xu
标识
DOI:10.1002/aenm.202506523
摘要
ABSTRACT Hard carbons are among the most promising anode materials for sodium‐ion batteries, yet synergistic architectural control across multiple scales to improve comprehensive Na + storage performances remains elusive. Herein, we propose a salt‐mediated micelle interfacial polymerization to fine nanospherical swelling/shrinkage and closed‐pore within nanoshells for excellent holistic Na + storage. Metal salts screening reveals that Mn 2+ promotes hollow sphere swelling via hydrolysis‐driven micelle expansion, while Cu 2+ oxidatively polymerizes monomer within micelles, causing shrinkage to solid spheres. The hollow architecture enables bidirectional Na + diffusion with >95% storage‐site utilization, outperforming unidirectional‐limited solid spheres with size‐dependent utilization. Meanwhile, this architecture, combined with 0D isotropy mitigates sodiation‐induced stress upon ultralong cycling. In situ salt‐induced expanded closed pores within the nanoscale shell enhance low‐potential capacity with fast kinetics. Such synergistic multi‐scale design leads to simultaneous exceptional high capacity of 324 mA g −1 , outstanding rate capability retention of 90.5% at 1 A g −1 , and unprecedented cyclic stability up to 20000 cycles with decay rate as low as 0.0014% per cycle. Negligible volume expansion (<0.0002 % per cycle) is observed for hollow spheres, nearly 15 times less than that of solid spheres (0.0026%). This work establishes fundamental design principle of multi‐scale architectural engineering for advanced hard carbon anodes.
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