掺锂提高了 V3O7 ⋅ H2O 纳米棒的锌离子水溶液储存性能

IF 3.5 4区 化学 Q2 ELECTROCHEMISTRY
Yingfang Hu, Siwen Zhang, Yujin Ren, Rongyuan Ge, Yaowen Shi, Xinyu Feng, Hui Li, Baohua Jia, Bosi Yin, Tianyi Ma
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引用次数: 0

摘要

水性锌离子电池(AZIBs)具有安全性高、环保和锌资源丰富等显著优势。钒基类层状氧化物是有希望成为锌离子电池阴极材料的候选材料;然而,它们面临着电导率低、循环稳定性差和 Zn2+ 储存能力有限等挑战。本研究采用水热法成功合成了 Li-V3O7 ⋅ H2O 电极材料。锂离子的掺杂使电极结构中的层间间距显著扩大,从而增强了离子迁移率,提高了离子传输速度和充放电速率。此外,间距的增加还能容纳更多的锌离子,从而提高比容量和储能能力。更重要的是,这种改性降低了结构应变,最大限度地减少了钒基材料的溶解,并在多次循环中保持了电极的完整性,从而提高了循环稳定性。因此,通过掺杂锂离子,V3O7 ⋅ H2O 电极的性能得到了大幅提升。锂-V3O7⋅H2O阴极在低电流时的比容量为 411.8 mAh g-1,在 4.0 A g-1 的条件下循环 4800 次仍能保持 83% 的容量,与原始 V3O7 ⋅H2O相比有显著提高。它具有出色的导电性、放电容量和循环稳定性,在未来的高性能储能领域大有可为。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Lithium Doping Enhances the Aqueous Zinc Ion Storage Performance of V3O7 ⋅ H2O Nanorods

Lithium Doping Enhances the Aqueous Zinc Ion Storage Performance of V3O7 ⋅ H2O Nanorods

Aqueous zinc-ion batteries (AZIBs) offer significant advantages, including high safety, environmental protection and abundant zinc sources. V-based layer-like oxides are promising candidates as cathode materials for ZIBs; however, they face challenges such as low electrical conductivity, poor cycling stability, and limited Zn2+ storage capacity. In this study, Li-V3O7 ⋅ H2O electrode materials were successfully synthesized using a hydrothermal method. The doping of lithium ions has led to a significant expansion of the interlayer spacing within the electrode structure, which enhances ion mobility and improves ion transport speed as well as charge-discharge rates. Additionally, the increased spacing allows for the accommodation of more zinc ions, resulting in greater specific capacity and energy storage. More importantly, this modification reduces structural strain, minimizes the dissolution of vanadium-based materials, and maintains electrode integrity over multiple cycles, thereby improving cycling stability. Consequently, the properties of V3O7 ⋅ H2O electrodes were substantially enhanced through lithium-ion doping. The Li-V3O7 ⋅ H2O cathode has a specific capacity of 411.8 mAh g−1 at low current and maintains 83 % of its capacity at 4.0 A g−1 for 4800 cycles, indicating a noteworthy improvement over pristine V3O7 ⋅ H2O. Exhibiting outstanding conductivity, discharge capacity, and cycling stability, it holds immense promise for future high-performance energy storage.

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来源期刊
ChemElectroChem
ChemElectroChem ELECTROCHEMISTRY-
CiteScore
7.90
自引率
2.50%
发文量
515
审稿时长
1.2 months
期刊介绍: ChemElectroChem is aimed to become a top-ranking electrochemistry journal for primary research papers and critical secondary information from authors across the world. The journal covers the entire scope of pure and applied electrochemistry, the latter encompassing (among others) energy applications, electrochemistry at interfaces (including surfaces), photoelectrochemistry and bioelectrochemistry.
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