Manipulating and quantifying temperature-triggered coalescence with microcentrifugation

Huanhuan Feng; Dmitry Ershov; Thomas Krebs; Karin Schroen; Martien A. Cohen Stuart; Jasper Van Der Gucht; Joris Sprakel

doi:10.1039/c4lc00773e

Manipulating and quantifying temperature-triggered coalescence with microcentrifugation

Huanhuan Feng
, Dmitry Ershov
, Thomas Krebs
, Karin Schroen
, Martien A. Cohen Stuart
, Jasper Van Der Gucht
, Joris Sprakel^*

^*Corresponding author for this work

Wageningen University & Research
Dutch Polymer Institute
FMC Separation Systems

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

25 Scopus citations

Abstract

In this paper we describe a new approach to quantify the stability and coalescence kinetics of thermally switchable emulsions using an imaging-based microcentrifugation method. We first show that combining synchronized high-speed imaging with microfluidic centrifugation allows the direct measurement of the thermodynamic stability of emulsions, as expressed by the critical disjoining pressure. We apply this to a thermoresponsive emulsion, allowing us to measure the critical disjoining pressure as a function of temperature. The same method, combined with quantitative image analysis, also gives access to droplet-scale details of the coalescence process. We illustrate this by measuring temperature-dependent coalescence rates and by analysing the temperature-induced switching between two distinct microscopic mechanisms by which dense emulsions can destabilise to form a homogeneous oil phase.

Original language	English
Pages (from-to)	188-194
Number of pages	7
Journal	Lab on a Chip
Volume	15
Issue number	1
DOIs	https://doi.org/10.1039/c4lc00773e
State	Published - 7 Jan 2015
Externally published	Yes

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title = "Manipulating and quantifying temperature-triggered coalescence with microcentrifugation",

abstract = "In this paper we describe a new approach to quantify the stability and coalescence kinetics of thermally switchable emulsions using an imaging-based microcentrifugation method. We first show that combining synchronized high-speed imaging with microfluidic centrifugation allows the direct measurement of the thermodynamic stability of emulsions, as expressed by the critical disjoining pressure. We apply this to a thermoresponsive emulsion, allowing us to measure the critical disjoining pressure as a function of temperature. The same method, combined with quantitative image analysis, also gives access to droplet-scale details of the coalescence process. We illustrate this by measuring temperature-dependent coalescence rates and by analysing the temperature-induced switching between two distinct microscopic mechanisms by which dense emulsions can destabilise to form a homogeneous oil phase.",

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AU - Feng, Huanhuan

AU - Ershov, Dmitry

AU - Krebs, Thomas

AU - Schroen, Karin

AU - Cohen Stuart, Martien A.

AU - Van Der Gucht, Jasper

AU - Sprakel, Joris

PY - 2015/1/7

Y1 - 2015/1/7

N2 - In this paper we describe a new approach to quantify the stability and coalescence kinetics of thermally switchable emulsions using an imaging-based microcentrifugation method. We first show that combining synchronized high-speed imaging with microfluidic centrifugation allows the direct measurement of the thermodynamic stability of emulsions, as expressed by the critical disjoining pressure. We apply this to a thermoresponsive emulsion, allowing us to measure the critical disjoining pressure as a function of temperature. The same method, combined with quantitative image analysis, also gives access to droplet-scale details of the coalescence process. We illustrate this by measuring temperature-dependent coalescence rates and by analysing the temperature-induced switching between two distinct microscopic mechanisms by which dense emulsions can destabilise to form a homogeneous oil phase.

AB - In this paper we describe a new approach to quantify the stability and coalescence kinetics of thermally switchable emulsions using an imaging-based microcentrifugation method. We first show that combining synchronized high-speed imaging with microfluidic centrifugation allows the direct measurement of the thermodynamic stability of emulsions, as expressed by the critical disjoining pressure. We apply this to a thermoresponsive emulsion, allowing us to measure the critical disjoining pressure as a function of temperature. The same method, combined with quantitative image analysis, also gives access to droplet-scale details of the coalescence process. We illustrate this by measuring temperature-dependent coalescence rates and by analysing the temperature-induced switching between two distinct microscopic mechanisms by which dense emulsions can destabilise to form a homogeneous oil phase.

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Manipulating and quantifying temperature-triggered coalescence with microcentrifugation

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