Breakup of pancake droplets flowing through a microfluidic constriction

•The breakup (i.e., snap-off) of pancake droplets presents novel behaviors.•Breakup of pancake droplets occurs at high capillary numbers and rear meniscus.•Daughter droplet size of pancake droplets is dependent of mother droplet size.•The velocity of pancake droplet is significant smaller than that...

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Bibliographic Details
Published in:Chemical engineering science 2020-07, Vol.220, p.115649, Article 115649
Main Authors: He, Long, Luo, Zhengyuan, Bai, Bofeng
Format: Article
Language:English
Subjects:
Breakup
Constriction
Microfluidic channel
Pancake droplets
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Summary:•The breakup (i.e., snap-off) of pancake droplets presents novel behaviors.•Breakup of pancake droplets occurs at high capillary numbers and rear meniscus.•Daughter droplet size of pancake droplets is dependent of mother droplet size.•The velocity of pancake droplet is significant smaller than that of continuous fluid.•A theoretical prediction of droplets snap-off is established. Due to its significance in oil recovery and droplet microfluidics, breakup of spherical droplets in a constriction (i.e., snap-off) is extensively studied. However, rectangular channels with large aspect ratios are commonly used in real applications, in which droplets usually present pancake shape. Since capillary pressures governing droplet’s snap-off depend strongly on droplet shape, we hypothesize that pancake droplets may exhibit different snap-off behaviors from spherical droplets. Via microfluidic experiments, we demonstrate that pancake droplets indeed present new snap-off behaviors in three aspects: (1) they snap off at high capillary numbers; (2) the interface breaks up at the rear meniscus instead of the front one; (3) the size of daughter droplets is dependent of mother droplet size instead of independent for spherical droplets. Besides, we reveal the underlying mechanism, i.e., pancake droplets show much lower velocity in the constriction than spherical droplets, via analyzing capillary pressures at the droplet’s two ends.
ISSN:0009-2509
1873-4405
DOI:10.1016/j.ces.2020.115649