Surfactant reorientation under shear: dynamic surface tension and droplet deformation

TL;DR

This paper models how surfactant molecules reorient under shear flow, affecting surface tension and droplet deformation, with implications for confined multiphase flows.

Contribution

It introduces a phase-field model that explicitly accounts for surfactant polarization and demonstrates shear-induced surface tension modification and droplet deformation behaviors.

Findings

Shear causes surfactant polarization to tilt, increasing effective surface tension.

Droplet deformation follows linear Taylor scaling at small capillary numbers.

Surfactants enhance droplet deformation by reducing surface tension.

Abstract

We study the deformation of a surfactant-covered droplet under shear flow using a phase-field model that explicitly accounts for both the surfactant concentration and its polarization, representing the average molecular orientation. We first consider a flat interface and show that an imposed tangential shear causes the surfactant polarization to tilt away from the interface normal. This reorientation reduces the ability of surfactants to lower the interfacial free energy, leading to an increase in the effective surface tension and demonstrating that surface tension can be dynamically modified by shear. We then examine droplet deformation under shear in both weakly and strongly confined geometries. In the weak-confinement regime, numerical results recover the linear Taylor scaling at small capillary numbers, while at larger capillary numbers they are accurately described by a modified Maffettone-Minale phenomenological model. The presence of surfactants enhances deformation through a reduction in the effective surface tension. In the strong-confinement regime, wall effects further increase droplet deformation, with results qualitatively captured by including the Shapira-Haber correction. Overall, our findings show that surfactant reorientation under flow provides a microscopic mechanism for shear-dependent surface tension and has significant implications for droplet deformation in confined multiphase flows.