arXiv:1906.08054 Abstract | arXiv Analytics

arXiv:1906.08054 [physics.flu-dyn]Abstract References Reviews Resources

Spontaneous shrinkage of droplet on wetting surface in phase-field model

Published 2019-06-18Version 1

Phase field theory is widely used to model multi-phase flows. A drop can shrink or grow spontaneously due to the redistribution of interface and bulk energies to minimize the system energy. In this paper, the spontaneous behaviour of a drop on a flat surface is investigated. It is found that there exists a critical radius dependent on the contact angle, the domain size and the interface width, below which the droplet will eventually disappear. In particular, the critical radius can be very large when the contact angle is hydrophilic. The theoretical prediction of the critical radius is verified numerically by simulating a drop on a surface with various contact angles, the domain sizes and the interface widths.

Comments: 10pages, 8 figures,

Categories: physics.flu-dyn

Keywords: phase-field model, wetting surface, spontaneous shrinkage, contact angle, critical radius

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