Characterization of Folding and Stretching in Mixing Enhancements

This research paper presents a 2D numerical model of an electrokinetic T-junction micromixer based on the stretching and folding theory presented by Ottino. Particle deformation was considered by simulating 2 $\mu m$ massless particles as 8-point square cells. Furthermore, stretching and folding definitions are proposed, compatible with a Lagrangian particle approach. Moreover, mixing homogeneity and consistency were measured in a 200 $\mu m$ square region of interest neighboring the outlet. Statistical analysis of the exiting mixing homogeneity at four different electric field conditions (93.5 V/cm, 109.8 V/cm, 126 V/cm and 117.9 V/cm, corresponding to a 23V, 27V, 29V and 31V potential difference) show that mixing consistency and homogeneity are not always increased with a higher electric field intensity, even after electrokinetic instabilities are formed, as increasingly unstable flow conditions decrease the ratio of folding to stretching ($m$), hindering the interaction between substances. Finally, an optimal proportion of stretching to folding was found for maximizing mixing efficiency at $m =0.0045$.
Comment: 17 pages, 7 figures