Lattice Boltzmann Simulation of Microfluidics with Non-uniform Zeta Potentials: Requirements of Flow Rate and Current Continuities

F. Tian, Baoming Li, D. Kwok
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引用次数: 2

Abstract

The characteristics of electrokinetic flow in a microchannel depend on both the nature of the surface potential, i.e. whether it is uniform or nonuniform, and the electric potential distribution along the channel. In this paper, the nonlinear Poisson-Boltzmann equation is used to model the electrical double layer and the Lattice Boltzmann Model coupled with the constraint of current continuity is used to simulate the flow field in a rectangular microchannel with step change surface potential. The results show that step change ion distribution caused by step change surface potential will influence significantly the electric potential distribution along the channel, the velocity profiles and the volumetric flow rate. This may indicate that if disturbance on the ion distribution due to nonuniform surface potential and velocity distortion is large and not negligible, the electric potential distribution along the channel in both pressure-driven and electroosmotic flow may not be linear.
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具有非均匀Zeta电位的微流体晶格玻尔兹曼模拟:流速和电流连续性的要求
微通道内的电动流动特性取决于表面电位的性质,即是均匀还是不均匀,以及沿通道的电势分布。本文采用非线性泊松-玻尔兹曼方程对双电层进行建模,并采用结合电流连续性约束的晶格玻尔兹曼模型对具有阶跃表面电位的矩形微通道内的流场进行模拟。结果表明,台阶变化表面电位引起的台阶变化离子分布对通道电位分布、速度分布和体积流量有显著影响。这可能表明,如果由于不均匀的表面电位和速度畸变对离子分布的干扰很大且不可忽略,则在压力驱动和电渗透流动中沿通道的电位分布都可能不是线性的。
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