Wenxu Shang , Wentao Yu , Xu Xiao , Yanyi Ma , Ziqi Chen , Meng Ni , Peng Tan
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引用次数: 10
Abstract
Aqueous rechargeable Zn-Co batteries feature intrinsic safety and excellent electrochemical performance, and zinc metal is cheap with abundant reserves. However, a key issue, self-discharge, which may be fatal to the application, is always overlooked. Herein, the self-discharge performance is investigated systematically for the first time, and in-depth charge–discharge mechanisms are analyzed. Based on a free-standing Co3O4 electrode, the insufficient utilization of the active material is found under a conventional galvanostatic charging process. Additionally, a dramatic attenuation in the open-circuit voltage is exhibited during the delay, leading to poor capacity retention. Through electrochemical tests and ex-situ characterization, the limited capacity and the severe self-discharge behavior are ascribed to the low amount and poor stability of the high valence state, respectively. Aiming at suppressing the self-discharge behavior, a novel charging protocol is proposed based on a new mechanism, which uses a time-controlling potentiostatic charging after the galvanostatic charging process. Using this strategy, the discharge capacity increases effectively by about 31.8% from 220 to 290 mA h g−1, and the capacity retention ratio after 10 h delay lifts from 72% to 90%. More importantly, the discharge capacity remains 100% after even 2500 cycles. This work puts forward a practical method for the operation of Zn-Co batteries, addresses the limiting issues for application, and greatly facilitates the improvement of this technology. Further, the results also inspire the research of other rechargeable Zn-based batteries.
锌钴水充电池具有本质安全、电化学性能优异、金属锌价格低廉、储量丰富等特点。然而,一个关键的问题,自放电,可能是致命的应用,往往被忽视。本文首次对其自放电性能进行了系统研究,并对其充放电机理进行了深入分析。基于独立的Co3O4电极,在常规的恒流充电过程中发现活性材料利用率不足。此外,在延迟期间,开路电压会出现急剧衰减,导致容量保持不良。通过电化学测试和非原位表征,认为其容量有限和自放电严重的原因分别是高价态数量少和稳定性差。为了抑制电池的自放电行为,提出了一种新的充电方案,该方案基于一种新的充电机制,即在恒流充电过程后进行时间控制的恒电位充电。采用该策略,放电容量在220 ~ 290 mA h g−1范围内有效提高了约31.8%,延迟10 h后的容量保持率从72%提高到90%。更重要的是,即使在2500次循环后,放电容量仍保持100%。本工作提出了一种实用的锌钴电池操作方法,解决了锌钴电池应用中的限制问题,极大地促进了锌钴电池技术的改进。同时,对其他可充电锌基电池的研究也有一定的启发作用。
期刊介绍:
Applied Energy serves as a platform for sharing innovations, research, development, and demonstrations in energy conversion, conservation, and sustainable energy systems. The journal covers topics such as optimal energy resource use, environmental pollutant mitigation, and energy process analysis. It welcomes original papers, review articles, technical notes, and letters to the editor. Authors are encouraged to submit manuscripts that bridge the gap between research, development, and implementation. The journal addresses a wide spectrum of topics, including fossil and renewable energy technologies, energy economics, and environmental impacts. Applied Energy also explores modeling and forecasting, conservation strategies, and the social and economic implications of energy policies, including climate change mitigation. It is complemented by the open-access journal Advances in Applied Energy.
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