Abstract
To have non-zero net flow in AC electroosmotic pumps, the electroosmosis (EO) has to be non-linear and asymmetric. This can be achieved due to ionic concentration polarization. This is known to occur close to micro-/nano-interfaces provided that the sizes of the nanopores are not too large compared to the Debye screening length. However, operation of the corresponding EO pumps can be quite sensitive to the solution concentration and, thus, unstable in practical applications. Concentration polarization of ion-exchange membranes is much more robust. However, the hydraulic permeability of the membrane is very low, which makes EO flows through them extremely small. This communication shows theoretically how this problem can be resolved via making scarce microscopic perforations in an ion-exchange membrane and putting it in series with an EO-active nano-porous medium. The problem of coupled flow, concentration and electrostatic-potential distributions is solved numerically by using finite-element methods. This analysis reveals that even quite scarce perforations of micron-scale diameters are sufficient to observe practically-interesting EO flows in the system. If the average distance between the perforations is smaller than the thickness of the EO-active layer, there is an effective homogenization of the electrolyte concentration and hydrostatic pressure in the lateral direction at some distance from the interface. The simulations show this distance to be somewhat lower than the half-distance between the perforations. On the other hand, when the surface fraction of perforations is sufficiently small (below a fraction of a percent) this "homogeneous" concentration is considerably reduced (or increased, depending on the current direction), which makes the EO strongly non-linear and asymmetric. This analysis provides initial guidance for the design of high-productivity and inexpensive AC electroosmotic pumps.
Highlights
PaperElectro-osmotic pumps are useful because they have no moving parts and can be miniaturized for applications in micro-Total-Analysis Systems.[1]
We have explored theoretically a new con guration exhibiting non-linear and asymmetric electroosmosis due to ionic concentration polarization
This is achieved in a layered system where aporous medium is sandwiched with a perforated ion-exchange membrane
Summary
Electro-osmotic pumps are useful because they have no moving parts and can be miniaturized for applications in micro-Total-Analysis Systems (mTAS).[1] Another interesting application is EO-generated “active” moisture removal through engineered sports tissues.[2,3]. Alternating Current EO pumps (ACEO) have the potential advantage of exhibiting no electrode reactions (provided that the voltage is not too high and/or the frequency is not too low). The absence of electrode reactions is a sine-qua-non in the application of “active” moisture removal because of the direct contact of the material with the human body. For an ACEO pump to produce net ows (over the AC period), the EO has to be asymmetric (its rate is dependent on the current direction). Considerable efforts have been devoted to the exploration of ACEO based on the concept of travelling-wave ACEO using asymmetric electrode arrays.[4,5,6,7,8,9,10]
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