Evaporation of binary liquids from a capillary tube

Lijun Thayyil Raju*, Christian Diddens, Javier Rodríguez-Rodríguez, Marjolein N. Van Der Linden, Xuehua Zhang, Detlef Lohse*, Uddalok Sen*

*Corresponding author for this work

Research output: Contribution to journalArticleAcademicpeer-review

1 Citation (Scopus)
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Abstract

Evaporation of multi-component liquid mixtures in confined geometries, such as capillaries, is crucial in applications such as microfluidics, two-phase cooling devices and inkjet printing. Predicting the behaviour of such systems becomes challenging because evaporation triggers complex spatio-temporal changes in the composition of the mixture. These changes in composition, in turn, affect evaporation. In the present work, we study the evaporation of aqueous glycerol solutions contained as a liquid column in a capillary tube. Experiments and direct numerical simulations show three evaporation regimes characterised by different temporal evolutions of the normalised mass transfer rate (or Sherwood number), namely, and, where is a normalised time. We present a simplistic analytical model that shows that the evaporation dynamics can be expressed by the classical relation. For small and medium, this expression results in the first and second of the three observed scaling regimes, respectively. This analytical model is formulated in the limit of pure diffusion and when the penetration depth of the diffusion front is much smaller than the length of the liquid column. When, finite-length effects lead to, i.e. the third regime. Finally, we extend our analytical model to incorporate the effect of advection and determine the conditions under which this effect is important. Our results provide fundamental insights into the physics of selective evaporation from a multi-component liquid column.

Original languageEnglish
Article numberA21
Number of pages30
JournalJournal of fluid mechanics
Volume983
Early online date21 Mar 2024
DOIs
Publication statusPublished - 25 Mar 2024

Keywords

  • UT-Hybrid-D
  • coupled diffusion and flow
  • microscale transport
  • condensation/evaporation

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