Net fluid flow induced by AC potentials applied to arrays of co-planar interdigitated microelectrodes is reported. Two types of microelectrode structures have been employed: arrays of unequal width electrodes subjected to a single AC signal, and arrays of identical electrodes subjected to a traveling-wave potential. A square glass chamber was constructed around the electrode arrays and filled with a concentration of KCl in water of conductivity around 1 mS/m. A map of the fluid velocity as a function of voltage (0-8 Vpp) and frequency (0.1-100 kHz) is presented for the traveling-wave array. In both microstructures, two fluid flow regimes have been observed: at small voltage amplitudes the fluid moves in a certain direction, and at higher voltage amplitudes the fluid flow is reversed. The fluid flow seems to be driven at the level of the electrodes in the two flow regimes. The observations at low voltages are in qualitative accordance with an AC electroosmotic model based upon the Debye-Huckel theory for the double layer.
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机译:报告了由施加到共平面叉指式微电极阵列上的交流电势引起的净流体流量。已经使用了两种类型的微电极结构:经受单个交流信号的宽度不相等的电极阵列,以及经受行波电势的相同电极的阵列。在电极阵列周围构造一个方形玻璃室,并用电导率约为1 mS / m的水中的KCl浓度填充。对于行波阵列,给出了流体速度与电压(0-8 Vpp)和频率(0.1-100 kHz)的关系图。在两个微观结构中,都观察到两种流体流动方式:在较小的电压幅度下,流体沿特定方向移动,而在较高的电压幅度下,流体反向流动。在两种流动方式下,似乎在电极的水平上驱动流体流动。在低电压下的观察定性地基于基于双层的Debye-Huckel理论的AC电渗模型。
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