Bubble coalescence in worm-like micellar solutions

TL;DR

This study investigates how the viscoelastic properties of worm-like micellar solutions influence bubble coalescence dynamics, revealing unique fluid behaviors and stages of film drainage leading to rupture.

Contribution

It provides new insights into the impact of viscoelasticity on bubble coalescence stages and fluid dynamic phenomena in worm-like micellar solutions.

Findings

Viscoelasticity modifies drainage and coalescence stages.

Observation of elastic recoil and thin film ripping.

Distinct drainage behaviors linked to micellar solution properties.

Abstract

Surfactants in aqueous solutions self-assemble in the presence of salt, to form long, flexible worm-like micelles (WLM). WLM solutions exhibit viscoelastic properties and are used in many applications, such as for cosmetic products, drag reduction and hydraulic fracturing. The dynamics of bubbles in WLM solutions are important considerations for the stability of many of these products. In this manuscript, we investigate the thin film drainage dynamics leading up to the coalescence of bubbles in WLM solutions. The salts and surfactant type and concentrations were chosen so as to have the viscoelastic properties of the tested WLM solutions span over two orders of magnitude in moduli and relaxation times. The various stages in drainage and coalescence - the formation of a thick region at the apex - a dimple, the thinning and washout of this dimple and the final stages of drainage before rupture, are modified by the viscoelasticity of the wormlike micellar solutions. As a result of the unique viscoelastic properties of the WLM solutions, we also observe a number of interesting fluid dynamic phenomena during the drainage process including elastic recoil, thin film ripping and single-step terminal drainage.