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Self-assembly of ellipsoidal particles at fluid-fluid interfaces with an empirical pair potential

[Display omitted] Colloidal particles adsorbed at fluid-fluid interfaces interact via mechanisms that can be specific to the presence of interfaces, for instance, lateral capillary interactions induced by nonspherical particles. Capillary interactions are highly relevant for self-assembly and the fo...

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Published in:	Journal of colloid and interface science 2019-01, Vol.534, p.205-214
Main Authors:	Luo, Alan M., Vermant, Jan, Ilg, Patrick, Zhang, Zhenkun, Sagis, Leonard M.C.
Format:	Article
Language:	English
Subjects:	Capillary interactions Ellipsoidal particles Empirical pair potential Fluid-fluid interfaces Self-assembly
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cited_by	cdi_FETCH-LOGICAL-c488t-e6c425542f1638dd992beff93c49810a0647079325a957c624694d6974b3dece3
cites	cdi_FETCH-LOGICAL-c488t-e6c425542f1638dd992beff93c49810a0647079325a957c624694d6974b3dece3
container_end_page	214
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container_start_page	205
container_title	Journal of colloid and interface science
container_volume	534
creator	Luo, Alan M. Vermant, Jan Ilg, Patrick Zhang, Zhenkun Sagis, Leonard M.C.
description	[Display omitted] Colloidal particles adsorbed at fluid-fluid interfaces interact via mechanisms that can be specific to the presence of interfaces, for instance, lateral capillary interactions induced by nonspherical particles. Capillary interactions are highly relevant for self-assembly and the formation of surface microstructures, however, these are very challenging to model due to the multibody nature of capillary interactions. This work pursues a direct comparison between our computational modelling approach and experimental results on surface microstructures formed by ellipsoidal particles. We begin by investigating the accuracy of using pairwise interactions to describe the multibody capillary interaction by contrasting exact two- and three-particle interaction energies and we find that the pairwise approximation appears reasonable for the experimentally relevant configurations studied. We then develop an empirical pair potential and use it in Monte-Carlo type simulations to efficiently model the structure formation process for relevant particle properties such as aspect ratio, contact angle and surface coverage, and succeed in reproducing our experimental observations where we spread sterically-stabilised ellipsoidal particles onto an oil-air interface at high surface coverage. At lower surface coverages, we find that the self-assembly process falls into the diffusion-limited colloid aggregation universality class.
doi_str_mv	10.1016/j.jcis.2018.08.114
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We then develop an empirical pair potential and use it in Monte-Carlo type simulations to efficiently model the structure formation process for relevant particle properties such as aspect ratio, contact angle and surface coverage, and succeed in reproducing our experimental observations where we spread sterically-stabilised ellipsoidal particles onto an oil-air interface at high surface coverage. 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We then develop an empirical pair potential and use it in Monte-Carlo type simulations to efficiently model the structure formation process for relevant particle properties such as aspect ratio, contact angle and surface coverage, and succeed in reproducing our experimental observations where we spread sterically-stabilised ellipsoidal particles onto an oil-air interface at high surface coverage. 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source	ScienceDirect Freedom Collection 2022-2024
subjects	Capillary interactions Ellipsoidal particles Empirical pair potential Fluid-fluid interfaces Self-assembly
title	Self-assembly of ellipsoidal particles at fluid-fluid interfaces with an empirical pair potential
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