Simulation Analysis of Contact Angles and Retention Forces of Liquid Drops on Inclined Surfaces

A simulation study of liquid drops on inclined surfaces is performed in order to understand the evolution of drop shapes, contact angles, and retention forces with the tilt angle. The simulations are made by means of a method recently developed for dealing with contact angle hysteresis in the public...

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Veröffentlicht in:	Langmuir 2012-08, Vol.28 (32), p.11819-11826
Hauptverfasser:	Santos, M. J, Velasco, S, White, J. A
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Sprache:	eng
Schlagworte:	Chemistry Exact sciences and technology General and physical chemistry Solid-liquid interface Surface physical chemistry
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container_title	Langmuir
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creator	Santos, M. J Velasco, S White, J. A
description	A simulation study of liquid drops on inclined surfaces is performed in order to understand the evolution of drop shapes, contact angles, and retention forces with the tilt angle. The simulations are made by means of a method recently developed for dealing with contact angle hysteresis in the public-domain Surface Evolver software. The results of our simulations are highly dependent on the initial contact angle of the drop. For a drop with an initial contact angle equal to the advancing angle, we obtain results similar to those of experiments in which a drop is placed on a horizontal surface that is slowly tilted. For drops with an initial contact angle equal to the mean between the advancing and the receding contact angles, we recover previous results of finite element studies of drops on inclined surfaces. Comparison with experimental results for molten Sn–Ag–Cu on a tilted Cu substrate shows excellent agreement.
doi_str_mv	10.1021/la3019293
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title	Simulation Analysis of Contact Angles and Retention Forces of Liquid Drops on Inclined Surfaces
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