Flow behavior of periodical electroosmosis in microchannel for biochips

This paper presents an analytical solution for periodical electroosmotic flows in two-dimensional uniform microchannel based on Poisson–Boltzmann equations for electric double layer (EDL) and Navier–Stokes equation for incompressible viscous fluid. Analytical results indicate that the velocity of periodical electroosmosis strongly depends on Reynolds number Re=ωh2/νRe=ωh2/ν, as well as on EDL properties and applied electric field. Slip velocity of EDL decreases as the Reynolds number increases. Electroosmotic velocity outside the EDL decreases, and lag phase angle of velocity increases as distance away from the channel wall increases. A wavelike velocity profile across the channel is found. An asymptotic solution for low Reynolds number is given in this paper. Periodical electroosmosis with low Reynolds has same velocity amplitude and a pluglike velocity profile as that of steady electroosmosis. Based on Debye–Hückel approximation, this paper also obtains a solution of periodical electroosmosis applicable to cases where the thickness of EDL is of the same order as half of channel width.

This paper presents an analytical solution for periodical electroosmotic flows in two-dimensional uniform microchannel. Analytical results indicate that the velocity of periodical electroosmosis strongly depends on Reynolds number Re=ωh2/νRe=ωh2/ν, as well as on EDL properties and applied electric field. A wavelike velocity profile across the microchannel is found, as shown in the following figure.Figure optionsDownload as PowerPoint slide