材料科学
涂层
焦耳加热
碳化
阴极
闪光灯(摄影)
碳纤维
化学工程
降级(电信)
纳米技术
热导率
热失控
热的
炭黑
热阴极
复合材料
焦耳(编程语言)
热传导
热冲击
作者
Zhuangzhi Li,Yong Wang,Haiyan Hu,Lang Qiu,Yao Xiao,Linsen Li,Zhenguo Wu,Xiaodong Guo
标识
DOI:10.1002/aenm.202503894
摘要
Abstract Carbon coating is an effective strategy for enhancing the conductivity of polyanionic cathode materials. However, conventional carbon coating processes suffer from loose carbon coatings and excessive unbound carbon, leading to exacerbated side reactions. Here, the Na 3 V 2 (PO 4 ) 3 (NVP) carbon coating process in real‐time is probed, revealing that the kinetic mismatch between carbon source carbonization and cathode material phase‐formation causes coating failure. By introducing flash Joule heating (FJH) technology, ultrafast thermal shock is leveraged to kinetically synchronize carbonization and phase‐formation, fundamentally eliminating sequential reaction stages, thereby constructing a 2‐nm‐thick uniform carbon coating on NVP. The FJH‐engineered NVP delivers 85 mAh g −1 at −40 °C, and retains 84% capacity after 3000 cycles at 30 C. The coating stabilizes interfaces, reduces resistance, enhances thermal stability, and mitigates runaway risks. The effective preparation of various polyanionic cathode materials confirmed the versatility of FJH method to improve the effect of carbon coating. These findings provide an effective strategy for designing high‐safety, long‐lifespan polyanionic cathode materials.
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