Irradiation-driven Evaporation of Micro Droplets in an Optical Trap

Small droplets are irradiated with visible and infrared light in many natural and industrial environments. One of the simplest ways to describe their evaporation is the D\(^2\)-Law. It states that the evaporation rate is proportional to \(t^{-1/2}\), and \(R^{-1}\). However, models like the D\(^2\)-...

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Bibliographic Details
Published in:arXiv.org 2024-12
Main Authors: Jugal Rakesh Shah, Huisman, Max, Deshmukh, Devendra, Hanstorp, Dag, Javier Tello Marmolejo
Format: Article
Language:English
Subjects:
Droplets
Evaporation rate
Internal combustion
Irradiation
Laser beam heating
Optical traps
Rocket engines
Water drops
Online Access:Get full text
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Summary:Small droplets are irradiated with visible and infrared light in many natural and industrial environments. One of the simplest ways to describe their evaporation is the D\(^2\)-Law. It states that the evaporation rate is proportional to \(t^{-1/2}\), and \(R^{-1}\). However, models like the D\(^2\)-Law do not account for the volumetric heating of light and the effect of strong irradiation on individual droplets is not fully understood. Here we show the effects of IR irradiation on optically levitated water droplets. We find that, under strong irradiation of up to \(10^8 W/m^2\), the droplet evaporation is initially driven by the heat from the laser following the power law \(dR / dt \sim R\), i.e. the inverse of the D\(^2\)-Law. Then, when the droplets shrink to 2 - 3 \(\mu\)m in radius a turnover occurs from irradiation-driven back to diffusion-driven evaporation. Our findings support the understanding of droplet evaporation in cases such as rocket engines or internal combustion, where the radiation from the flame will heat water and fuel droplets.
ISSN:2331-8422