期刊
INTERNATIONAL JOURNAL OF HEAT AND MASS TRANSFER
卷 201, 期 -, 页码 -出版社
PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.ijheatmasstransfer.2022.123665
关键词
Gravitational fingering; Thermodynamic instability; Phase separation; Drop formation
In this study, the phase separation process of partially miscible and miscible binary systems in a vertical Hele-Shaw cell is numerically analyzed. The governing equations for momentum and mass transfer are newly implemented, considering the Korteweg force and thermodynamic stability. The study demonstrates the formation of droplets in metastable or unstable regions, which enhances the phase separation process.
In this study, the phase separation process of partially miscible and miscible binary systems in a vertical Hele-Shaw cell is numerically analyzed. The governing equations of a partially miscible binary system for momentum and mass transfer under buoyancy-driven fluid motion are newly implemented by taking into account both the Korteweg force and thermodynamic stability. The thermodynamic instability is reflected in the mass transfer using the modified Cahn-Hilliard equation and the Flory-Huggins Gibbs free energy for mixing. The onset of fingering and drop formation are demonstrated under buoyancy-driven motion depending on the repulsive interaction parameter (?). When x is higher than ?(c) , droplet formation in a metastable or unstable region induced by convective mixing ultimately results in enhanced phase separation. Meanwhile, for a hydrodynamic stable system, the diffusional mixing is not strong enough to induce drop formation in stable and metastable regions. The Korteweg force resists the drop formation process induced by convection motion, determining the drop size and wavelength on the long fingers. For a metastable or unstable binary system, high Korteweg force results in the larger size of the droplet. Even in a fully miscible system, i.e.,? < ?(c), the Korteweg force still affects the system by making it stable, especially with an increase in the gradient interaction parameter (K). This numerical study provides a deep understanding of phase separation in a thermodynamic binary system under buoyance-driven convection motion.
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