阳极
电解质
阴极
锌
材料科学
电流密度
枝晶(数学)
铜
电化学
电镀(地质)
电偶阳极
水溶液
电极
金属
化学工程
分析化学(期刊)
冶金
化学
阴极保护
色谱法
几何学
工程类
量子力学
地球物理学
物理化学
数学
地质学
物理
作者
Shuhua Shan,Mihir Parekh,Rong Kou,Donghai Wang,Christopher D. Rahn
标识
DOI:10.1149/1945-7111/acf4c2
摘要
The cycle life and power density of Zn metal batteries depend on the anode electrodeposition morphology, including the formation of metal dendrites, and impedance, respectively. This paper investigates the influence of aqueous ZnSO 4 electrolyte convection through a copper mesh anode on Zn electrodeposition morphology and current densities. Electrochemical experiments in a specially designed flow-through cell with a Zn metal cathode reveal that the electrolyte flow from the cathode through the anode improves Zn deposition morphology and reduces impedance at concentrations ranging from 0.01 to 1 mol l −1 . Small flow rates at millimeters per second double the current densities. The electrodeposition morphology and current density are positively impacted at Peclet number larger than 1. At these flow rates, the Zn plating is more smooth, compact, uniformly deposited around the wire, and dense than that in the stagnant electrolyte. Zn-Cu asymmetric cell cycling tests at 50 mA cm −2 show that flow-through electrolyte can significantly increase the cell lifespan from 18 cycles in static electrolyte to 1300 cycles at a flow rate of 0.5 mm s −1 . Numerical analysis illustrates that the flow-through electrolyte replenishes consumed zinc ions at the electrode surface and suppresses dendrite growth by maintaining a uniform current density distribution.
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