Effects of particle size on the electrocoalescence dynamics and arrested morphology of liquid marbles

Yage Zhang; Chentianyi Yang; Shuai Yuan; Xiaoxue Yao; Youchuang Chao; Yang Cao; Qingchun Song; Alban Sauret; Bernard P. Binks; Ho Cheung Shum

doi:10.1016/j.jcis.2021.09.187

Effects of particle size on the electrocoalescence dynamics and arrested morphology of liquid marbles

Yage Zhang
, Chentianyi Yang
, Shuai Yuan
, Xiaoxue Yao
, Youchuang Chao
, Yang Cao
, Qingchun Song
, Alban Sauret
, Bernard P. Binks
, Ho Cheung Shum^*

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

12 Citations (Scopus)

Abstract

Hypothesis: The coalescence of bare droplets when surface tension dominates always results in one larger spherical droplet. In contrast, droplets coated with particles may be stabilized into non-spherical structures after arrested coalescence, which can be achieved by different approaches, such as changing the particle surface coverage. The size of particles coating the initial liquid marbles can be used to control the coalescence dynamics and the resulting morphology of arrested droplets.
Experiment: We characterized the electrocoalescence of liquid marbles coated with particles ranging from hundred nanometers to hundred micrometers. The electrocoalescence was recorded using high-speed imaging.
Findings: When the electrocoalescence initiates, particles jam and halt the relaxation of the marbles at different stages, resulting in four possible final morphologies that are characterized using the Gaussian curvature at the neck region. The four regimes are total coalescence, arrested puddle coalescence, arrested saddle coalescence, and non-coalescence. The coalescence is initiated at the center of the contact zone, independent of the particle size. Small particles show little resistance to the coalescence, while marbles coated by large particles demonstrate a viscous-like behavior, indicated by the growth of the liquid bridge and the damping. The present study provides guidelines for applications that involve the formulation of liquid marbles with complex morphologies.
© 2021 Elsevier Inc.

Original language	English
Pages (from-to)	1094-1104
Journal	Journal of Colloid and Interface Science
Volume	608
Issue number	Part 1
Online published	12 Oct 2021
DOIs	https://doi.org/10.1016/j.jcis.2021.09.187
Publication status	Published - 15 Feb 2022
Externally published	Yes

Funding

The authors would like to thank Prof. Huisheng Zhang, Dr. Zhou Liu, Dr. Tiantian Kong, Dr. Yuan Liu, and Dr. Qingchuan Li for helpful discussions on this work. This research was supported by the General Research Fund [grant numbers 17329516, 17304017] from the Research Grants Council of Hong Kong; the Excellent Young Scientists Fund (Hong Kong and Macau) [grant number 21922816] from the National Natural Science Foundation of China (NSFC); and the Sichuan Science and Technology Program [grant number 2018JZ0026].

Research Keywords

Arrested structure
Coalescence
Liquid marble

RGC Funding Information

RGC-funded

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10.1016/j.jcis.2021.09.187

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title = "Effects of particle size on the electrocoalescence dynamics and arrested morphology of liquid marbles",

abstract = "Hypothesis: The coalescence of bare droplets when surface tension dominates always results in one larger spherical droplet. In contrast, droplets coated with particles may be stabilized into non-spherical structures after arrested coalescence, which can be achieved by different approaches, such as changing the particle surface coverage. The size of particles coating the initial liquid marbles can be used to control the coalescence dynamics and the resulting morphology of arrested droplets. Experiment: We characterized the electrocoalescence of liquid marbles coated with particles ranging from hundred nanometers to hundred micrometers. The electrocoalescence was recorded using high-speed imaging. Findings: When the electrocoalescence initiates, particles jam and halt the relaxation of the marbles at different stages, resulting in four possible final morphologies that are characterized using the Gaussian curvature at the neck region. The four regimes are total coalescence, arrested puddle coalescence, arrested saddle coalescence, and non-coalescence. The coalescence is initiated at the center of the contact zone, independent of the particle size. Small particles show little resistance to the coalescence, while marbles coated by large particles demonstrate a viscous-like behavior, indicated by the growth of the liquid bridge and the damping. The present study provides guidelines for applications that involve the formulation of liquid marbles with complex morphologies. {\textcopyright} 2021 Elsevier Inc.",

keywords = "Arrested structure, Coalescence, Liquid marble",

author = "Yage Zhang and Chentianyi Yang and Shuai Yuan and Xiaoxue Yao and Youchuang Chao and Yang Cao and Qingchun Song and Alban Sauret and Binks, \{Bernard P.\} and Shum, \{Ho Cheung\}",

year = "2022",

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doi = "10.1016/j.jcis.2021.09.187",

language = "English",

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pages = "1094--1104",

journal = "Journal of Colloid and Interface Science",

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}

TY - JOUR

T1 - Effects of particle size on the electrocoalescence dynamics and arrested morphology of liquid marbles

AU - Zhang, Yage

AU - Yang, Chentianyi

AU - Yuan, Shuai

AU - Yao, Xiaoxue

AU - Chao, Youchuang

AU - Cao, Yang

AU - Song, Qingchun

AU - Sauret, Alban

AU - Binks, Bernard P.

AU - Shum, Ho Cheung

PY - 2022/2/15

Y1 - 2022/2/15

N2 - Hypothesis: The coalescence of bare droplets when surface tension dominates always results in one larger spherical droplet. In contrast, droplets coated with particles may be stabilized into non-spherical structures after arrested coalescence, which can be achieved by different approaches, such as changing the particle surface coverage. The size of particles coating the initial liquid marbles can be used to control the coalescence dynamics and the resulting morphology of arrested droplets. Experiment: We characterized the electrocoalescence of liquid marbles coated with particles ranging from hundred nanometers to hundred micrometers. The electrocoalescence was recorded using high-speed imaging. Findings: When the electrocoalescence initiates, particles jam and halt the relaxation of the marbles at different stages, resulting in four possible final morphologies that are characterized using the Gaussian curvature at the neck region. The four regimes are total coalescence, arrested puddle coalescence, arrested saddle coalescence, and non-coalescence. The coalescence is initiated at the center of the contact zone, independent of the particle size. Small particles show little resistance to the coalescence, while marbles coated by large particles demonstrate a viscous-like behavior, indicated by the growth of the liquid bridge and the damping. The present study provides guidelines for applications that involve the formulation of liquid marbles with complex morphologies. © 2021 Elsevier Inc.

AB - Hypothesis: The coalescence of bare droplets when surface tension dominates always results in one larger spherical droplet. In contrast, droplets coated with particles may be stabilized into non-spherical structures after arrested coalescence, which can be achieved by different approaches, such as changing the particle surface coverage. The size of particles coating the initial liquid marbles can be used to control the coalescence dynamics and the resulting morphology of arrested droplets. Experiment: We characterized the electrocoalescence of liquid marbles coated with particles ranging from hundred nanometers to hundred micrometers. The electrocoalescence was recorded using high-speed imaging. Findings: When the electrocoalescence initiates, particles jam and halt the relaxation of the marbles at different stages, resulting in four possible final morphologies that are characterized using the Gaussian curvature at the neck region. The four regimes are total coalescence, arrested puddle coalescence, arrested saddle coalescence, and non-coalescence. The coalescence is initiated at the center of the contact zone, independent of the particle size. Small particles show little resistance to the coalescence, while marbles coated by large particles demonstrate a viscous-like behavior, indicated by the growth of the liquid bridge and the damping. The present study provides guidelines for applications that involve the formulation of liquid marbles with complex morphologies. © 2021 Elsevier Inc.

KW - Arrested structure

KW - Coalescence

KW - Liquid marble

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Effects of particle size on the electrocoalescence dynamics and arrested morphology of liquid marbles

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Corrigendum to “Effects of particle size on the electrocoalescence dynamics and arrested morphology of liquid marbles” [J. Colloid Interf. Sci. 608(Part 1) (2022) 1094–1104]

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