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Autores principales: Li, Jing, Wen, Kaiqiang, Xiao, Ke, Chen, Xiaoming, Wu, Chen-Xu
Formato: Preprint
Publicado: 2024
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Acceso en línea:https://arxiv.org/abs/2405.16245
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author Li, Jing
Wen, Kaiqiang
Xiao, Ke
Chen, Xiaoming
Wu, Chen-Xu
author_facet Li, Jing
Wen, Kaiqiang
Xiao, Ke
Chen, Xiaoming
Wu, Chen-Xu
contents Due to the potential application of regulating droplet shape by external fields in microfluidic technology and micro devices, it becomes increasingly important to understand the shape formation of a droplet in the presence of an electric field. How to understand and determine such a deformable boundary shape at equilibrium has been a long-term physical and mathematical challenge. Here, based on the theoretical model we propose, and combining the finite element method and the gradient descent algorithm, we successfully obtain the droplet shape by considering the contributions made by electrostatic energy, surface tension energy, and gravitational potential energy. We also carry out scaling analyses and obtain an empirical critical disruption condition with a universal scaling exponent 1/2 for the contact angle in terms of normalized volume. The master curve fits both the experimental and the numerical results very well.
format Preprint
id arxiv_https___arxiv_org_abs_2405_16245
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Shape of a droplet on a surface in the presence of an external field and its critical disruption condition
Li, Jing
Wen, Kaiqiang
Xiao, Ke
Chen, Xiaoming
Wu, Chen-Xu
Soft Condensed Matter
Fluid Dynamics
Due to the potential application of regulating droplet shape by external fields in microfluidic technology and micro devices, it becomes increasingly important to understand the shape formation of a droplet in the presence of an electric field. How to understand and determine such a deformable boundary shape at equilibrium has been a long-term physical and mathematical challenge. Here, based on the theoretical model we propose, and combining the finite element method and the gradient descent algorithm, we successfully obtain the droplet shape by considering the contributions made by electrostatic energy, surface tension energy, and gravitational potential energy. We also carry out scaling analyses and obtain an empirical critical disruption condition with a universal scaling exponent 1/2 for the contact angle in terms of normalized volume. The master curve fits both the experimental and the numerical results very well.
title Shape of a droplet on a surface in the presence of an external field and its critical disruption condition
topic Soft Condensed Matter
Fluid Dynamics
url https://arxiv.org/abs/2405.16245