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Enrichment of Scavenged Particles in Jet Drops Determined by Bubble Size and Particle Position
Summary
Researchers demonstrated that when bubbles burst in contaminated water, particles larger than previously assumed can be transported into jet drops and become highly concentrated, with enrichment depending on bubble size and particle position on the bubble surface.
When small bubbles rupture in a contaminated water source, the resulting liquid jet breaks up into droplets that can aerosolize solid particulates such as bacteria, viruses, and microplastics. Particles collected on the bubble surface have the potential to become highly concentrated in the jet drops, dramatically increasing their impact. It has been assumed that only particles small enough to fit within a thin microlayer surrounding the bubble can be transported into its influential top jet drop. Yet here, we demonstrate that not only can larger particles be transported into this jet drop, but also that these particles can exceed previous enrichment measurements. Through experiments and simulations, we identify the prerupture location of the liquid that develops into the top jet drop and model how interfacial rearrangement combines with the bubble size, particle size, and the angular distribution of particles on the bubble surface to set the particle enrichment.
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