液态金属电池模型中金属-电解质界面稳定性的实验观察

IF 0.3 4区工程技术 Q4 MECHANICS Magnetohydrodynamics Pub Date : 2021-07-01 DOI:10.22364/mhd.57.2.3

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摘要

在背景垂直磁场下，电流通过方形截面电池中液体镓和水性电解质的界面。表面波的振荡增量是根据在可变电流强度下的电势测量来计算的。该表面也可以通过透明的侧壁进行视觉观察。对于高达1.5的Sele参数，不会出现增长的表面波。相反，准静态表面变形是由金属和电解质的旋转引起的。该表面变形的最大高度大约与电流成比例地增加。图7，参考文献15。

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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Experimental observation of metal-electrolyte interface stability in a model of liquid metal battery

An electric current is passed through the interface of liquid gallium and aqueous electrolyte in a square cross-section cell under a background vertical magnetic field. The oscillation increment of surface waves is calculated from potential measurements at variable current strengths. The surface is also visually observed through transparent side walls. No growing surface waves occur for the Sele parameter as high as 1.5. Instead, a quasi-static surface deformation is caused by the rotation of the metal and electrolyte. The maximum height of this surface deformation increases approximately in proportion to the current. Figs 7, Refs 15.

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