Evaporation dynamics of a surrogate respiratory droplet in a vortical environment

Hypothesis: Vortex droplet interaction is crucial for understanding the route of disease transmission through expiratory jet where several such embedded droplets continuously interact with vortical structures of different strengths and sizes. Experiments: A train of vortex rings with different vortex strength, quantified with vortex Reynolds number (Re' = 0; 53; 221; 297) are made to interact with an isolated levitated droplet, and the evolution dynamics is captured using shadowgraphy, particle image velocimetry (PIV), and backlight imaging technique. NaCl-DI water solution of 0, 1, 10 and 20 wt% concentrations are used as test fluids for the droplet. Findings: The results show the dependence of evaporation characteristics on vortex strength, while the crystallization dynamics was found to be independent of it. A reduction of 12.23% and 14.6% in evaporation time was seen in case of de-ionized (DI) water and 1% wt NaCl solution respectively in presence of vortex ring train at Re' = 221. In contrast to this, a minimal reduction in evaporation time (0.6% and 0.9% for DI water and 1% wt NaCl solution, respectively) is observed when Re' is increased from 221 to 297. The mechanisms for evaporation time reduction due to enhancement of convective heat and mass transfer from the droplet and shearing away of vapor layer by vortex ring interaction are discussed in this work. (c) 2022 Elsevier Inc. All rights reserved.

Automated summary

This study reveals the impact of vortex droplet interaction on evaporation characteristics, showing that evaporation time is dependent on vortex strength while crystallization dynamics is independent of it.