Density Matching for Microencapsulation of Field Responsive Suspensions of Non-Brownian Microparticles

Samuel R. Wilson-Whitford; Jinghui Gao; James F. Gilchrist

doi:10.1021/acs.jpcb.4c02288

Density Matching for Microencapsulation of Field Responsive Suspensions of Non-Brownian Microparticles

Samuel R. Wilson-Whitford, Jinghui Gao, James F. Gilchrist

Research output: Contribution to journal › Article › peer-review

Abstract

When forming composite microcapsules through the emulsification of a dispersed phase laden with microparticles, one will find that the microparticles become irreversibly embedded in the resulting microcapsule membrane. This phenomenon, known as Pickering stabilization, is detrimental when the end function of the microcapsules relies on the mobility of encapsulated microparticles within the capsule core. In this work, a robust microencapsulation route using density matching of non-Brownian microparticles in a binary solvent is shown to easily and effectively encapsulate particles, with >90% of particles retaining mobility within the microcapsules, without the necessity for prior chemical/physical modifications to the microparticles. This is proposed as a generalized method to be used for all manner of particle chemistries, shapes, and sizes.

Original language	English
Number of pages	6
Journal	The Journal of Physical Chemistry B
Volume	128
Issue number	26
Early online date	15 May 2024
DOIs	https://doi.org/10.1021/acs.jpcb.4c02288
Publication status	Published - 4 Jul 2024

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10.1021/acs.jpcb.4c02288Licence: CC BY 4.0

wilson-whitford-et-al-2024-density-matching-for-microencapsulation-of-field-responsive-suspensions-of-non-brownian
Copyright © 2024 The Authors. Published by American Chemical Society. This publication is licensed under CC-BY 4.0 (https://creativecommons.org/licenses/by/4.0/).
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title = "Density Matching for Microencapsulation of Field Responsive Suspensions of Non-Brownian Microparticles",

abstract = "When forming composite microcapsules through the emulsification of a dispersed phase laden with microparticles, one will find that the microparticles become irreversibly embedded in the resulting microcapsule membrane. This phenomenon, known as Pickering stabilization, is detrimental when the end function of the microcapsules relies on the mobility of encapsulated microparticles within the capsule core. In this work, a robust microencapsulation route using density matching of non-Brownian microparticles in a binary solvent is shown to easily and effectively encapsulate particles, with >90% of particles retaining mobility within the microcapsules, without the necessity for prior chemical/physical modifications to the microparticles. This is proposed as a generalized method to be used for all manner of particle chemistries, shapes, and sizes.",

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AU - Wilson-Whitford, Samuel R.

AU - Gao, Jinghui

AU - Gilchrist, James F.

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N2 - When forming composite microcapsules through the emulsification of a dispersed phase laden with microparticles, one will find that the microparticles become irreversibly embedded in the resulting microcapsule membrane. This phenomenon, known as Pickering stabilization, is detrimental when the end function of the microcapsules relies on the mobility of encapsulated microparticles within the capsule core. In this work, a robust microencapsulation route using density matching of non-Brownian microparticles in a binary solvent is shown to easily and effectively encapsulate particles, with >90% of particles retaining mobility within the microcapsules, without the necessity for prior chemical/physical modifications to the microparticles. This is proposed as a generalized method to be used for all manner of particle chemistries, shapes, and sizes.

AB - When forming composite microcapsules through the emulsification of a dispersed phase laden with microparticles, one will find that the microparticles become irreversibly embedded in the resulting microcapsule membrane. This phenomenon, known as Pickering stabilization, is detrimental when the end function of the microcapsules relies on the mobility of encapsulated microparticles within the capsule core. In this work, a robust microencapsulation route using density matching of non-Brownian microparticles in a binary solvent is shown to easily and effectively encapsulate particles, with >90% of particles retaining mobility within the microcapsules, without the necessity for prior chemical/physical modifications to the microparticles. This is proposed as a generalized method to be used for all manner of particle chemistries, shapes, and sizes.

UR - https://pubs.acs.org/doi/10.1021/acs.jpcb.4c02288

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DO - 10.1021/acs.jpcb.4c02288

M3 - Article

VL - 128

JO - The Journal of Physical Chemistry B

JF - The Journal of Physical Chemistry B

IS - 26

ER -

Density Matching for Microencapsulation of Field Responsive Suspensions of Non-Brownian Microparticles

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