Short-Time Force Response during the Impact of a Droplet with Gas Bubbles

TL;DR

This study numerically investigates how gas bubbles within a droplet influence the impact forces on a solid surface, revealing that bubbles can significantly buffer the impact even before contact occurs.

Contribution

It introduces a numerical model combining boundary integral and lubrication theories to analyze the effect of internal gas bubbles on droplet impact forces.

Findings

Gas bubbles inside droplets significantly influence impact forces.

Larger and near-surface bubbles dampen impact more effectively.

Multiple small bubbles can have effects comparable to or greater than single large bubbles.

Abstract

The presence of gas or vapour bubbles may strongly influence the forces that occur during the impact of a liquid mass onto a solid. Here, we study this effect numerically, in a well-controlled manner, by simulating the short-time interaction between an impacting droplet and a solid surface, mediated by the gas layer between droplet and solid just before collision, in the presence and absence of bubbles. A boundary integral method is used to simulate the falling droplet, the mediating air layer is modeled using lubrication theory, whereas uniform gas bubbles are added to the droplet that obey a polytropic equation of state. We show that the presence of gas bubbles inside the droplet can have a significant influence on the force exerted on the substrate, even before touchdown. This is due to the transmission of load from the solid, through the gas layer and finally into the bubbly droplet, buffering the impact. We simulate different bubble configurations, modifying their number, size, shape and initial position. It is found that larger bubbles, as well as those close to the impact zone, dampen the collision more as compared to small bubbles or the ones that are far from the droplet's surface. In addition, multiple small bubbles are shown to have a similar or even greater effect as a single large bubble.