Zhang Yanyi, Yang Xinxin, Hu Yixuan, Hu Kailong, Lin Xi, Liu Xingjun, Reddy Kolan Madhav, Xie Guoqiang, Qiu Hua-Jun
School of Materials Science and Engineering, Harbin Institute of Technology, Shenzhen, 518055, China.
Frontier Research Center for Materials Structure, School of Materials Science and Engineering, Shanghai Jiao Tong University, Shanghai, 200240, China.
Small. 2022 Apr;18(17):e2200787. doi: 10.1002/smll.202200787. Epub 2022 Mar 28.
Zn-ion batteries (ZIBs) using aqueous electrolyte, recently, have been a hot topic owing to the high safety, low cost, and high specific energy capacity. However, the formation of dendrite and side reactions on the Zn anode during cycling inhibit the application of ZIBs. An advanced Zn anode by alloying a small amount of Li and Mn with Zn is hereby reported. It is found that Li and Mn can form cationic ions which restrain lateral diffusion of Zn ions and regulate zinc electrodeposition through the electrostatic shield mechanism. As a result, the formation of Zn dendrite is greatly inhibited. This process also mitigates the formation of Zn-based byproduct and Zn passivation. Consequently, the symmetric ZnLiMn/ZnLiMn cell presents a small overpotential of 30 mV at 1 mA cm , greatly enhanced cycling durability (1000 h at a current density of 1 mA cm ), and a dendrite-free morphology after cycles. Moreover, the authors find that the ZnLiMn alloy has greatly enhanced mechanical properties. The assembled ZnLiMn/MnO full cell can retain 96% capacity after 400 cycles at 1 C. Thus, the alloying low-cost Li/Mn strategy is very promising for large-scale production of dendrite-free Zn electrode in rechargeable ZIBs.
近年来,使用水性电解质的锌离子电池(ZIBs)由于其高安全性、低成本和高比能量容量而成为热门话题。然而,循环过程中锌阳极上枝晶的形成和副反应抑制了ZIBs的应用。在此报道了一种通过将少量锂和锰与锌合金化制成的先进锌阳极。研究发现,锂和锰可以形成阳离子,通过静电屏蔽机制抑制锌离子的横向扩散并调节锌的电沉积。结果,大大抑制了锌枝晶的形成。该过程还减轻了锌基副产物的形成和锌的钝化。因此,对称的ZnLiMn/ZnLiMn电池在1 mA cm 时具有30 mV的小过电位,大大提高了循环耐久性(在1 mA cm 的电流密度下为1000小时),并且循环后无枝晶形态。此外,作者发现ZnLiMn合金的机械性能大大增强。组装的ZnLiMn/MnO全电池在1 C下400次循环后可保持96%的容量。因此,低成本的锂/锰合金化策略对于大规模生产可充电ZIBs中无枝晶的锌电极非常有前景。
