Stability and tip streaming of a surfactant-loaded drop in an extensional flow. Influence of surface viscosity

We study numerically the nonlinear stationary states of a droplet covered with an insoluble surfactant in a uniaxial extensional flow. We calculate both the eigenfunctions to reveal the instability mechanism and the time-dependent states resulting from it, which provides a coherent picture of the ph...

Full description

Saved in:
Bibliographic Details
Published inJournal of fluid mechanics Vol. 934
Main Authors Herrada, M.A., Ponce-Torres, A., Rubio, M., Eggers, J., Montanero, J.M.
Format Journal Article
LanguageEnglish
Published Cambridge, UK Cambridge University Press 10.03.2022
Subjects
Approximation
Damping
Deformation
Droplets
Eigenfunctions
Eigenvectors
Flow stability
Fluid mechanics
Inertia
Interfaces
Interfacial stresses
JFM Papers
Perturbation
Pollutants
Polymer blends
Reynolds number
Simulation
Streaming
Surfactants
Viscosity
Wind stress
capillary flows
drops
breakup
Online AccessGet full text

Cover

More Information
Summary:We study numerically the nonlinear stationary states of a droplet covered with an insoluble surfactant in a uniaxial extensional flow. We calculate both the eigenfunctions to reveal the instability mechanism and the time-dependent states resulting from it, which provides a coherent picture of the phenomenon. The transition is of the saddle-node type, both with and without surfactant. The flow becomes unstable under stationary linear perturbations. Surfactant considerably reduces the interval of stable capillary numbers. Inertia increases the droplet deformation and decreases the critical capillary number. In the presence of the surfactant monolayer, neither the droplet deformation nor the stability is significantly affected by the droplet viscosity. The transient state resulting from instability is fundamentally different for drops with and without surfactant. Tip streaming occurs only in the presence of surfactants. The critical eigenmode leading to tip streaming is qualitatively the same as that yielding the central pinching mode for a clean interface, which indicates that the small local scale characterizing tip streaming is set during the nonlinear droplet deformation. The viscous surface stress does not significantly affect the droplet deformation and the critical capillary number. However, the damping rate of the dominant mode considerably decreases for viscous surfactants. Interestingly, shear viscous surface stress considerably alters the tip streaming arising in the supercritical regime, even for very small surface viscosities. The viscous surface stresses alter the balance of normal interfacial stresses and affect the surfactant transport over the stretched interface.
ISSN:0022-1120
1469-7645
DOI:10.1017/jfm.2021.1118