Long Jiang, Yizhao Chai, Dongdong Ji, Liwei Li, Le Li, Bingan Lu, Dongmin Li, Jiang Zhou
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引用次数: 0
Abstract
Aqueous zinc-ion batteries (AZIBs) present a promising option for next-generation batteries given their high safety, eco-friendliness, and resource sustainability. Nonetheless, the practical application of zinc anodes is hindered by inevitable parasitic reactions and dendrite growth. Here, zinc alloy layers (i.e., ZnCo and ZnFe alloys) were rationally constructed on the zinc surface by chemical displacement reactions. The alloying process exposes more (002) planes of the ZnCo anode to guide the preferential and dendrite-free zinc deposition. Furthermore, the ZnCo alloy layer not only effectively inhibits water-induced side reactions but also accelerates electrode kinetics, enabling highly reversible zinc plating/stripping. As a result, the ZnCo anode achieves a Coulombic efficiency of 99.2% over 1300 cycles, and the ZnCo symmetric cell exhibits a long cycle life of over 2000 h at 4.4 mA cm. Importantly, the ZnCo//NHVO full cell retains a high discharge capacity of 218.4 mAh g after 800 cycles. Meanwhile, the ZnFe-based symmetric cell also displays excellent cycling stability over 2500 h at 1.77 mA cm. This strategy provides a facile anode modification approach toward high-performance AZIBs.
锌离子水电池(AZIBs)具有高度安全性、生态友好性和资源可持续性,是下一代电池的理想选择。然而,锌阳极的实际应用受到不可避免的寄生反应和枝晶生长的阻碍。在这里,我们通过化学置换反应在锌表面合理地构建了锌合金层(即锌钴合金和锌铁合金)。合金化过程暴露了锌钴阳极的更多 (002) 平面,从而引导了锌的优先和无枝晶沉积。此外,锌钴合金层不仅能有效抑制水引起的副反应,还能加速电极动力学,实现高度可逆的镀锌/剥离。因此,锌钴阳极在 1300 次循环中的库仑效率达到了 99.2%,锌钴对称电池在 4.4 mA cm 的条件下可实现超过 2000 小时的长循环寿命。重要的是,ZnCo//NHVO 全电池在 800 次循环后仍能保持 218.4 mAh g 的高放电容量。同时,基于锌钴的对称电池在 1.77 mA cm 的条件下也显示出了超过 2500 小时的卓越循环稳定性。这种策略为实现高性能 AZIB 提供了一种简便的阳极改性方法。
期刊介绍:
Green Energy & Environment (GEE) is an internationally recognized journal that undergoes a rigorous peer-review process. It focuses on interdisciplinary research related to green energy and the environment, covering a wide range of topics including biofuel and bioenergy, energy storage and networks, catalysis for sustainable processes, and materials for energy and the environment. GEE has a broad scope and encourages the submission of original and innovative research in both fundamental and engineering fields. Additionally, GEE serves as a platform for discussions, summaries, reviews, and previews of the impact of green energy on the eco-environment.