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科研动态
博士生杨静波,彭创的论文在CHEMICAL ENGINEERING JOURNAL刊出
发布时间:2022-07-15 14:41:53     发布者:易真     浏览次数:

标题: Self-assembled titanium-deficient undoped anatase TiO2 nanoflowers for ultralong-life and high-rate Li+/Na+ storage

作者: Yang, JB (Yang, Jingbo); Huang, MJ (Huang, Moujie); Xu, LY (Xu, Lingyun); Xia, X (Xia, Xin); Peng, C (Peng, Chuang)

来源出版物: CHEMICAL ENGINEERING JOURNAL : 445 文献号: 136638 DOI: 10.1016/j.cej.2022.136638 出版年: OCT 1 2022

摘要: Anatase TiO2 is a promising safe and high-rate anode for Li- and Na-ion batteries owing to its moderate redox potential and multi-dimensional ion diffusion paths. However, the capacity, rate and cycle life of anatase TiO2 are severely hindered by the low Li+/Na+ diffusion coefficients. Ti vacancies have been predicted to significantly improve Li+ diffusion kinetics by previous theoretical calculations. However, experimental evidence is still lacking because the existing methods to create Ti vacancies commonly rely on aliovalent doping, i.e., the coexistence of Ti vacancies and foreign anions precludes revelation of the true role and contribution of Ti vacancies alone. The current work reports the synthesis of mesoporous flower-like titanium-deficient anatase TiO2 (TDAT). The formation mechanisms of the Ti vacancies and the micro-architectures are tentatively discussed. Its undoped nature allows elucidation of the unambiguous roles of Ti vacancies on Li+/Na+ storage. Electrochemical results show high capacity, high rate and ultra-long cycle stability for both Li+/Na+ storage in TDAT. DFT calculations reveal that the presence of Ti vacancies results in reduced energy barrier for Li+/Na+ intercalation, enhanced diffusion kinetics, additional Li+/Na+ storage sites and diffusion pathways. For Na+ storage, it achieves a high capacity of 219.9 mAh g+ 1 at 50 mA g+ 1, and superior stability over ultra-long 15,000 cycle test at 2000 mA g+ 1. This work complements with the prevailing view of anion vacancy for improved Li+/Na+ storage.

作者关键词: Titanium dioxide; Cation vacancy; Li and Na-ion battery; Ion diffusion; DFT calculations

地址: [Yang, Jingbo; Huang, Moujie; Xu, Lingyun; Peng, Chuang] Wuhan Univ, Sch Resource & Environm Sci, Wuhan 430072, Peoples R China.

[Xia, Xin] North China Elect Power Univ, Coll New Energy, Beijing 102206, Peoples R China.

通讯作者地址: Peng, C (通讯作者),Wuhan Univ, Sch Resource & Environm Sci, Wuhan 430072, Peoples R China.

Xia, X (通讯作者),North China Elect Power Univ, Coll New Energy, Beijing 102206, Peoples R China.

电子邮件地址: xxia@ncepu.edu.cn; chuang.peng@whu.edu.cn

影响因子:16.744


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