Structure formation by nanosilica particles suspended in levitated droplet

TL;DR

This study investigates the behavior and structure formation of nanosilica particles in vaporizing droplets levitated acoustically, revealing concentration-dependent migration patterns and dynamic ring structures during heating.

Contribution

It provides detailed insights into nanosilica particle migration, flow dynamics, and structure formation within levitated droplets under laser heating, a novel investigation in this context.

Findings

Recirculation within droplets decreases with higher viscosity.

Particles migrate to form horizontal rings at concentrations above 1.9%.

Vertical ring reorientation occurs due to force imbalance.

Abstract

Vaporization of liquid droplets containing particles has been studied extensively for its applications in combustion, thermal coating, ink-jet printing, spray cooling, drug delivery, and surface patterning. Droplets containing solid particles show a preferential solute-migration during drying process. Recently we carried out experiments with vaporizing droplet suspended in an acoustic levitator. In this work, we present detailed study of a laser irradiated droplet containing nanosilica particles. Infrared and High speed imaging of the heating process for different concentrations of nanosilica revealed an interesting solute migration pattern. Further investigation with Particle Image Velocimetry shows presence of strong recirculation within the levitated droplet. It also reveals that with increasing viscosity of the liquid the strength of this recirculation decreases. Due to the droplets rotation about the levitator axis, a centrifugal force also dominated the flow field within the droplet. High speed imaging shows that initial stage of heating is dominated by sharper diameter reduction. At the end of this stage the droplet takes a bowl shape. Next stage, which is termed as structure formation shows different characteristics for higher and lower concentrations. For nanosilica concentration of less than 1.3%, the bowl shape remains unaltered with further heating. On the other hand, for concentration greater than 1.9%, due to stronger centrifugal effect than recirculation, the particles migrate towards the equator plane creating horizontal ring structure. The horizontal ring very soon starts oscillating about the levitator axis. This creates an imbalance of forces resulting in reorientation of the ring. Thus a vertical ring is created.