How viscous bubbles collapse: topological and symmetry-breaking instabilities in curvature-driven hydrodynamics

TL;DR

This paper investigates the nonlinear surface dynamics of viscous bubbles during rapid depressurization, revealing topological and symmetry-breaking instabilities driven by curvature variations, and proposes a nonlinear curvature-driven pattern formation mechanism.

Contribution

It uncovers the role of curvature variations in driving nonlinear instabilities and pattern formation in viscous bubble surfaces, extending understanding beyond linear stability analysis.

Findings

Identification of topological instability and front propagation in bubble flattening

Observation of symmetry-breaking radial wrinkles with growing amplitude

Proposal of a nonlinear curvature-driven mechanism for pattern selection

Abstract

The duality between deformations of elastic bodies and non-inertial flows in viscous liquids has been a guiding principle in decades of research. However, this duality is broken when a spheroidal or other doubly-curved liquid film is suddenly forced out of mechanical equilibrium, as occurs e.g. when the pressure inside a liquid bubble drops rapidly due to rupture or controlled evacuation. In such cases the film may evolve through a non-inertial yet geometrically-nonlinear surface dynamics, which has remained largely unexplored. We reveal the driver of such dynamics as temporal variations in the curvature of the evolving surface. Focusing on the prototypical example of a floating bubble that undergoes rapid depressurization, we show that the bubble surface evolves via a topological instability and a subsequent front propagation, whereby a small planar zone nucleates and expands in the spherically-shaped film, bringing about hoop compression and triggering another, symmetry-breaking instability and radial wrinkles that grow in amplitude and invade the flattening film. Our analysis reveals the dynamics as a non-equilibrium branch of "Jellium" physics, whereby a rate-of-change of surface curvature in a viscous film is akin to charge in an electrostatic medium that comprises polarizable and conducting domains. We explain key features underlying recent experiments and highlight a qualitative inconsistency between the prediction of linear stability analysis and the observed "wavelength" of surface wrinkles. Our analysis points to the existence of a nonlinear curvature-driven mechanism for pattern selection in viscous flows.