Litcius/Paper detail

Size amplification of jet drops due to insoluble surfactants

Jun Eshima, Tristan Aurégan, Palas Kumar Farsoiya, Stéphane Popinet, Howard A. Stone, Luc Deike

2025Physical Review Fluids6 citationsDOIOpen Access PDF

Abstract

Surface bubbles in the environment or engineering configurations, such as the ocean-atmosphere interface, sparkling wine, or during volcanic eruptions typically live on contaminated surfaces. A particularly common type of contamination is surface active agents (surfactants). We consider the effect of insoluble surfactant on jet drop formation by bubble bursting. Contrary to the observed trend that surfactants decrease the ejected drop radius for bubbles with precursor capillary waves, we find that surfactants increase the ejected drop radius for bubbles without precursor capillary waves—a regime characteristic of small bubbles. Consequently, the results have fundamental implications for understanding aerosol distributions in contaminated conditions. We find that the trend reversal is due to the effect of Marangoni stresses on the focusing of the collapsing cavity. We demonstrate quantitative agreement on the jet velocity and drop size between laboratory experiments and numerical simulations by using the measured surface tension dependence on surfactant concentration as the equation of state for the simulations.

Topics & Concepts

Surface tensionDrop (telecommunication)Pulmonary surfactantMarangoni effectCapillary actionBubbleMechanicsJet (fluid)RADIUSAerosolMaterials scienceChemistryBreak-UpWeber numberCapillary numberDrop impactContaminationCapillary waveWork (physics)ThermodynamicsSpinning drop methodFluid Dynamics and Heat TransferNanomaterials and Printing TechnologiesFluid Dynamics and Thin Films