par Machrafi, Hatim;Rednikov, Alexei 
;Colinet, Pierre ;Dauby, Pierre
Référence Physical review. E, Statistical, nonlinear, and soft matter physics, 91, 5, 053018
Publication Publié, 2015-05-26
;Colinet, Pierre ;Dauby, PierreRéférence Physical review. E, Statistical, nonlinear, and soft matter physics, 91, 5, 053018
Publication Publié, 2015-05-26
Article révisé par les pairs
| Résumé : | A one-sided model of the thermal Marangoni instability owing to evaporation into an inert gas is developed. Two configurations are studied in parallel: a horizontal liquid layer and a spherical droplet. With the dynamic gas properties being admittedly negligible, one-sided approaches typically hinge upon quantifying heat and mass transfer through the gas phase by means of transfer coefficients (like in the Newton's cooling law), which in dimensionless terms eventually corresponds to using Biot numbers. Quite a typical arrangement encountered in the literature is a constant Biot number, the same for perturbations of different wavelengths and maybe even the same as for the reference state. In the present work, we underscore the relevance of accounting for its wave-number dependence, which is especially the case in the evaporative context with relatively large values of the resulting effective Biot number. We illustrate the effect in the framework of the Marangoni instability thresholds. As a concrete example, we consider HFE-7100 (a standard refrigerant) for the liquid and air for the inert gas. |
