We present an experimental and numerical investigation of induced charge electroosmosis (ICEO) on a planar electrode surface directly in contact with a high conductivity electrolytic solution. Symmetric rolls of ICEO flow were produced on the electrode by placing it in an AC electric field. The slip velocity was measured for a range of AC voltages and frequencies using micro particle image velocimetry (μPIV). The slip velocity was also calculated by finite element simulations based on a linear and a nonlinear model of electrical double layer, respectively. The (iPIV measurements were found to be much lower (two and half orders of magnitude) than the velocities predicted by the linear model. The linear model is valid only under Debye Huckel approximation (Φ 《 k_BT / e = 25 mVolt at room temperature) which does not hold true for practical situations. The nonlinear model, on the other hand, predicts velocities which are lower than the linear model and closer to the experimental values. The nonlinearity reduces discrepancy between experimental and numerical results by approximately an order of magnitude. The nonlinear model accounts for nonlinear capacitance of the double layer and lateral conduction of charge in the double layer.
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机译:我们提出了在与高电导率电解液直接接触的平面电极表面上的感应电荷电渗(ICEO)的实验和数值研究。通过将电极置于交流电场中,在电极上产生对称的ICEO流动。使用微粒图像测速仪(μPIV)在一定范围的交流电压和频率下测量滑移速度。还分别基于双电层的线性和非线性模型,通过有限元模拟计算了滑移速度。 (发现iPIV测量值比线性模型预测的速度低得多(两个半个数量级)。线性模型仅在Debye Huckel近似下有效(Φ《 k_BT / e = 25 mVolt在室温下)另一方面,非线性模型预测的速度低于线性模型但更接近实验值,非线性可将实验结果与数值结果之间的差异减少大约一个数量级。非线性模型考虑了双层的非线性电容和双层中电荷的横向传导。
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