Analysis Of Mixing Efficiency In An Electroosmotically Micromixer With Heterogeneous Wall Charge Distribution

Document Type : Original Article

Authors

Abstract

In this paper, numerical investigation of a flat passive micromixer with heterogeneous surface properties that the flow through it, is driven by the electroosmotic flow have been presented. The governing equations, which consist of a Laplace equation for the distribution of external electric potential, a Poisson equation for the distribution of electric double layer potential, modified Navier-Stokes equations for the flow field, the Nernst-Planck equation for the distribution of ions concentration have been solved numerically for an incompressible steady flow of a Newtonian fluid using the finite-volume method. The key features of an ideal electro-osmotic flow with uniform zeta potential has been compared with analytical solutions for the ionic concentration and velocity fields for the validation of the numerical scheme. Results show that the arrangement of the heterogeneous surface properties has a significant impact on the efficiency of mixing. Maximum mixing efficiency is related to the condition that the asymmetry in the wall of the heterogeneous arrangement loads increase. The increase in intensity of the electric charge with constant power load of the electroosmotic micropump enhances the efficiency of mixing.

Keywords

References

1. Wang, M., Wang, J.K. , Chen, S.Y. and Pan, N., "Electrokinetic pumping effects of charged porous media in microchannels using the lattice Poisson–Boltzmann method", J. Colloid Inter f. Sci.
No. 304, pp. 246–253, (2006).
2. Bhattacharyya, S. and Nayak, A.K., "Electroosmotic flow in micro/nanochannels with surface potential heterogeneity: An analysis through the Nernst–Planck model with convection effect", Colloids and Surfaces A: Physicochem. Eng., No. 339, pp. 167–177, (2009).
3. Chang, C.C. and Yang, R-J "Electrokinetic mixing in microfluidic systems", Microfluid Nanofluid, No. 3, pp. 501–525, (2007).
4. Kamholz, A.E., Weigl, B.H., Finlayson, B.A. and Yager P., "Quantitative analysis of molecular interactive in microfluidic channel: the Tsensor", Anal Chem., No. 71, pp. 5340–5347, (1999).
5. Ismagilov, R.F., Stroock, A.D., Kenis P.J.A, Whitesides, G.M. and Stone, H.A., "Experimental and theoretical scaling laws for transverse diffusive broadening in two-phase laminar flow in microchannels", Appl. Phys. Lett., No. 76, pp. 2376–2378, (2000).
6. Anderson, J.L., Idol, W.K., "Electroosmosisthrough pores with nonuniformly charged walls", Chem. Eng. Commun., No. 38, pp. 93–106, (1985).
7. Ajdari, A., "Electro-osmosis on inhomogeneous charged surfaces", Phys Rev Lett, No. 75, pp.
755–758, (1995).
8. Stroock, A.D., Dertinger, S., K.W., Ajdari, A., Mezic, I., Stone, H.A. and Whitesides, G.M., "Chaotic mixer for microchannels", Science, No. 295, pp. 647–65, (2002).
9. Fushinobu, K. and Nakata, M., "An experimental and numerical study of a liquid mixing device for Microsystems", Trans ASME J Electronic Packaging, No. 127, pp. 141–146, (2005).
10. Wang, J.K., Wang, M. and Li, Z.X., "Lattice Boltzmann simulations of mixing enhancement by the electroosmotic flow in microchannels", Mod. Phys. Lett. B, No. 19, pp. 1515–1518, (2005).
11. Tang, GH. , Li, Z., Wang, J.K. , He, Y.L. , Tao, W.Q., "Electroosmotic flow mixing in microchannels with the lattice Boltzmann Method", J Appl Phys, No. 100, 094908, (2006).
12. Tang, Z., Hong, S., Djukic, D., Modi, V., West, AC., Yardley, J. and Osgood, R.M., "Electrokinetic flow control for composition modulation in a microchannel", J Micromech Microeng, No. 12,
pp. 870–877, (2002).
13. Mirbozorgi, S.A., Niazmand, H. and Renksizbulut, M., "Electro-osmotic flow in reservoir-connected flat microchannels with non-uniform zeta potential", J. Fluid Engineering, No. 128, pp. 1133-1143, (2006.(
Send comment about this article
CAPTCHA Image
Journal Of Applied and Computational Sciences in Mechanics
Volume 25, Issue 2 - Serial Number 2
October 2014
Pages 97-110

Files

Share

How to cite

Statistics