电负性
阴极
结构稳定性
离子
材料科学
结晶学
替代(逻辑)
化学物理
再分配(选举)
格子(音乐)
扩散
密度泛函理论
电子
活化能
化学稳定性
电阻抗
化学工程
晶格常数
化学
极化(电化学)
计算化学
无机化学
理论(学习稳定性)
泄漏(经济)
纳米技术
电子迁移率
作者
Jingyao Zeng,Lei Sun,Jinqiang Gao,Weishun Jian,Haoji Wang,Wenyuan Li,Ningyun Hong,Baichao Zhang,Jiangnan Huang,Bai Song,Wentao Deng,Guoqiang Zou,Hongshuai Hou,Xiaobo Ji
出处
期刊:ACS Nano
[American Chemical Society]
日期:2025-09-08
卷期号:19 (36): 32432-32443
被引量:9
标识
DOI:10.1021/acsnano.5c08681
摘要
The integration of Mn in Na4Mn1.5Fe1.5(PO4)2P2O7 (NMFPP) enhances the energy density but compromises the Na+ mobility and structural stability due to limited electron hopping and pronounced Jahn–Teller effects. To address this, a structurally compatible anionic substitution strategy is implemented by partially replacing PO43– with bulkier and less electronegative SiO44– groups. The reinforced cathode exhibits enhanced rate performance, which is attributed to lattice expansion induced by the larger SiO44– units, thereby facilitating Na+ diffusion and reducing impedance during charge–discharge processes, as supported by GITT and DRT analyses. In addition, the improved cycling stability results from the lower electronegativity of Si, which enables SiO44– to accommodate local charge redistribution without triggering structural collapse, as evidenced by reduced lattice volume fluctuations observed in in situ XRD. Consequently, Na4Mn1.5Fe1.5(PO4)1.95(SiO4)0.05P2O7 achieves a capacity retention of up to 85.42% for 500 cycles at 1 C and 80.54% over 1500 cycles at 5 C. These findings highlight anion substitution as a promising strategy for optimizing polyanionic frameworks toward high-performance sodium-ion batteries.
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