Yujun Bai , Jiali Qin , Jiaxuan Cai , Huiling Zhu , Tao Li , Yanxiang Wang , Yongxin Qi
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引用次数: 3
摘要
在碳化过程中,具有CN键的聚丙烯腈(PAN)可以转化为氮掺杂碳,这通过补偿Li2ZnTi3O8(LZTO)阳极的不足来提高电子导电性。在本研究中,通过将均匀的PAN/LZTO粉末混合物在约800℃的氮气流中碳化5小时来对LZTO进行改性,以在LZTO颗粒周围均匀地涂覆氮掺杂的碳,从而获得氮掺杂的LZTO。当电流密度从0.1增加到1.6 a g−1时,PAN-60表现出74.8%的容量保持率,即使在0.5 a g−l下进行1100次循环后,其充电/放电容量也为250.1/250.8 mAh g−1。结构和成分分析以及电化学测试表明,均匀的氮掺杂碳涂层和氮掺杂的LZTO有利于电子转移,而氮掺杂引起的LZTO缺陷促进了锂离子的迁移。增强的电子和离子电导率有利于缓解循环过程中的极化,因此有助于优化性能。
Simultaneously enhancing the electronic and ionic conductivities of Li2ZnTi3O8 via modification with polyacrylonitrile-derived carbon for high-performance anodes
Polyacrylonitrile (PAN) with CN bonds can be converted to nitrogen-doped carbon during carbonization, which enhances electronic conductivity by compensating for the deficiency of the Li2ZnTi3O8 (LZTO) anode. In this study, LZTO was modified by carbonizing a homogeneous PAN/LZTO powder mixture at approximately 800 ℃ for 5 h in nitrogen stream to uniformly coat nitrogen-doped carbon around the LZTO particles and to yield nitrogen-doped LZTO. PAN-60 exhibited a capacity retention of 74.8% as the current density increased from 0.1 to 1.6 A g−1, and had charge/discharge capacities of 250.1/250.8 mAh g−1 even after 1100 cycles at 0.5 A g−1. Structural and compositional analysis along with electrochemical tests showed that the uniform nitrogen-doped carbon coating and the nitrogen-doped LZTO favor electron transfer, while the defects induced by nitrogen-doping in LZTO promote Li-ion migration. The enhanced electronic and ionic conductivities are favorable to alleviate the polarization during cycling, and thus are responsible for the optimized performance.
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