Conventionally, a 1-D microanofluidic device, whose nanochannel bridged two microchannels, was widely chosen in the fundamental electrokinetic studies; however, the configuration had intrinsic limitations of the time-consuming and labor intensive tasks of filling and flushing the microchannel due to the high fluidic resistance of the nanochannel bridge. In this work, a pseudo 1-D microanofluidic device incorporating air valves at each microchannel was proposed for mitigating these limitations. High Laplace pressure formed at liquid/air interface inside the microchannels played as a virtual valve only when the electrokinetic operations were conducted. The identical electrokinetic behaviors of the propagation of ion concentration polarization layer and current voltage responses were obtained in comparison with the conventional 1-D microanofluidic device by both experiments and numerical simulations. Therefore, the suggested pseudo 1-D microanofluidic device owned not only experimental conveniences but also exact electrokinetic responses.
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