Bimetal-Initiated Concerted Zn Regulation Enabling Highly Stable Aqueous Zn-Ion Batteries

IF 4.6 4区 化学 Q2 ELECTROCHEMISTRY
Hong Yin, Yuliang Liu, Yifeng Zhu, Fengxiang Ye, Guangliang Xu, Mengfang Lin, Wenbin Kang
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Abstract

Aqueous zinc ion batteries are highly sought after for the next generation of sustainable energy storage systems. However, their development is significantly impeded by the presence of undesired zinc dendrites, which greatly reduce their cycle life. It is well-received that surface passivation by introducing foreign metals represents a compelling measure to enhance the stability of Zn anodes. Nevertheless, the vast potential of effecting concerted interplay between multiple metal elements for enhanced overall performance in Zn ion batteries remains elusive, due to the overwhelming challenge in creating uniform textures from hetero-units and understanding the mechanism underlying the synergistic performance gain. In this work, an innovative bimetallic overlaying strategy is proposed that renders possible the synergy between AgZn3 and CuZn5 in effecting uniform Zn deposition in a laterally confined and compact manner. The seeded growth of Zn on the bimetal-modulated interface effectively reduces the nucleation potential barrier, yielding a low nucleation overpotential (25 mV). In full cell testing with a commercial MnO2 applied as the cathode, superb cycling stability, surpassing the results reported in previous works, is achieved. The cell delivers an outstanding remaining capacity of 215 mA h g−1 after 300 cycles with almost no capacity degradation observed. The simple and highly efficient bimetal design, which synergizes the strengths of distinct metals, has the potential to drive innovations in the development of multicomponent aqueous Zn batteries with exceptional performance.
双金属引发的锌协同调控实现高稳定性水性锌离子电池
锌离子水电池是下一代可持续储能系统的首选。然而,它们的发展却因不受欢迎的锌枝晶的存在而严重受阻,这大大降低了它们的循环寿命。人们普遍认为,通过引入外来金属进行表面钝化是提高锌阳极稳定性的有效措施。然而,由于从异种单元中产生均匀的质地以及了解协同增效的内在机制是一项巨大的挑战,因此在锌离子电池中实现多种金属元素之间的协同作用以提高整体性能的巨大潜力仍然难以实现。在这项工作中,提出了一种创新的双金属叠层策略,使 AgZn3 和 CuZn5 能够协同作用,以横向限制和紧凑的方式实现均匀的锌沉积。锌在双金属调制界面上的种子生长有效降低了成核电位障碍,从而产生了较低的成核过电位(25 mV)。在使用商用二氧化锰作为阴极的完整电池测试中,电池实现了极佳的循环稳定性,超过了以前工作中报告的结果。经过 300 次循环后,电池的剩余容量高达 215 mA h g-1,几乎没有观察到容量衰减。这种简单而高效的双金属设计能协同不同金属的优势,有望推动具有卓越性能的多组分锌水电池的创新发展。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Batteries
Batteries Energy-Energy Engineering and Power Technology
CiteScore
4.00
自引率
15.00%
发文量
217
审稿时长
7 weeks
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