Electrohydrodynamic interaction between droplet pairs in confined shear flow

TL;DR

This study investigates how electric fields influence the movement and interaction of deformable droplets in confined shear flow, revealing controllable droplet trajectories and stability in microfluidic environments.

Contribution

It introduces a combined numerical and asymptotic model to predict droplet trajectories and demonstrates electric field modulation of droplet motion and stability in confined shear flow.

Findings

Electric field can switch droplet motion between passing over and reversing.

Droplet trajectories depend on initial separation distance.

Electric field can prevent droplet coalescence, stabilizing emulsions.

Abstract

The present study deals with the numerical as well as asymptotic analysis of the electrohydrodynamic interaction between two deformable droplets in a confined shear flow. Considering both the phases as leaky dielectric, we have performed numerical simulations to study the effect of channel confinement on the drop trajectories in the presence of a uniform electric field. Two important varieties of motion are identified in the present analysis, namely (i) the reversing motion and (ii) the passing over motion. The study suggests that conversion of the passing over motion to the reversing motion or vice versa is possible via modulating the strength of the imposed electric field. Such a conversion of the pattern of droplet migration is also possible in a confined domain due to change in different electrical properties of the system. The present numerical model is also able to predict the pattern of the trajectory of individual droplets depending on the initial distance separating the two. For example, a smaller initial distance results in a reversing motion whereas a passing over motion is predicted when the distance between the droplets is significantly large. However, the final positions of the droplets are found to be independent of their initial positions. Interestingly, presence of electric field is found to prevent droplet coalescence to a certain extent depending on its strength, thus rendering the emulsion stable. A small deformation asymptotic model is also developed under the assumption of negligible fluid inertia to support the numerical results for the limiting case of an unbounded flow. The current investigation successfully presents a novel technique to predict the precise positions of a system of droplets in a micro-channel and how electric field can be used as a tool to modulate droplet trajectories in an emulsion.