Dynamics of evaporating, interconnected droplets

TL;DR

This paper investigates the complex fluid exchange dynamics between interconnected evaporating droplets, revealing how shape changes and bifurcations lead to flow reversal driven by evaporation and pressure differences.

Contribution

It introduces a detailed analysis of evaporation-driven flow reversal in interconnected droplets, highlighting the role of shape changes and bifurcations in the process.

Findings

Flow between droplets is driven by pressure differences and can reverse direction.

Shape changes during evaporation influence fluid transport and flow stability.

A supercritical pitchfork bifurcation underpins the flow dynamics and shape switching.

Abstract

We report on the dynamics of a pair of sessile droplets that are connected by a microchannel, yet open to the atmosphere and hence free to evaporate. Our results reveal that fluid exchange between droplets occurs via a pumping flow driven by differences in hydrostatic and Laplace pressure between the two droplets. Evaporation causes the droplets to slowly lose volume and change shape, which subsequently affects the fluid transport between them. We observe that, for equal contact areas, a larger droplet typically feeds a smaller droplet during evaporation and the flow in the connecting channel is unidirectional. However, for unequal contact areas, the flow can reverse in the connecting channel following a sudden switch in dropletshape that occurs during evaporation. A stability,analysis reveals that the dynamics of the exchange flow are underpinned by a supercritical pitchfork bifurcation. Evaporative volume loss permits the droplet pair to step through a sequence of quasi-stationary states determined by the instantaneous volume of the system. Enforcing unequal contact area unfolds the bifurcation such that droplet-shape switching and the associated flow reversal can be understood in terms of a jump from the disconnected to the connected branch of the bifurcation. This establishes symmetry breaking as a mechanism to induce evaporation-driven flow reversal in connected droplets.