Studying coalescence at different lengthscales: from films to droplets

Emmanouil Chatzigiannakis; Yun Chen; Rana B Bachnak; Cari S. Dutcher; Jan Vermant

doi:10.1007/s00397-022-01365-w

Studying coalescence at different lengthscales: from films to droplets

Emmanouil Chatzigiannakis, Yun Chen, Rana B Bachnak, Cari S. Dutcher, Jan Vermant

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

14 Scopus citations

Abstract

The hydrodynamics of thin films is an important factor when it comes to the stability and rheology of multiphasic materials, such as foams, emulsions, and polymer blends. However, there have so far been only limited experimental studies addressing the dynamics of individual free-standing thin films at conditions similar to those encountered on macroscopic scales. In this article, we study a well-characterized system of a water-in-oil emulsion stabilized by a non-ionic surfactant (SPAN80) close to its CMC. We employ a dynamic thin film balance, to study the dynamics of freestanding films under both constant and time-varied pressure drops. We compare with the recently published results of Narayan et al. (2020) on colliding droplets of the same system with a hydrodynamic microfluidic trap, and show for the first time that agreement between the two lengthscales is possible, which indicates that the coalescence is indeed dominated by the dynamics in the film. We then address the scatter in the coalescence times and show that it can be affected by extrinsic factors, as well as by variations in the collision angle. Finally, we discuss the difficulties of extracting insight on the coalescence mechanism from coalescence time distributions when different effects such as impurities, small pressure variations, collision angle variations, and possible Marangoni-related instabilities are at play.

Original language	English (US)
Pages (from-to)	745-759
Number of pages	15
Journal	Rheologica Acta
Volume	61
Issue number	10
DOIs	https://doi.org/10.1007/s00397-022-01365-w
State	Published - Oct 2022

Bibliographical note

Funding Information:
EC and JV would like to thank the ETH Energy Science Center Partnership with Shell for the financial support. CSD would like to acknowledge that this material is based upon work supported by the Humphreys Engineer Center Support Activity under Contracts No. W912HQ20C0041, corresponding to DOD Strategic Environmental Research and Development Program (SERDP) projects WP19-1407. The DOD SERDP support includes support for YC. CSD would also like to acknowledge support by Donaldson Company, including support for RB.

Publisher Copyright:
© 2022, The Author(s).

Keywords

Coalescence
Drainage
Film dynamics
Marangoni
Surfactant

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10.1007/s00397-022-01365-w

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title = "Studying coalescence at different lengthscales: from films to droplets",

abstract = "The hydrodynamics of thin films is an important factor when it comes to the stability and rheology of multiphasic materials, such as foams, emulsions, and polymer blends. However, there have so far been only limited experimental studies addressing the dynamics of individual free-standing thin films at conditions similar to those encountered on macroscopic scales. In this article, we study a well-characterized system of a water-in-oil emulsion stabilized by a non-ionic surfactant (SPAN80) close to its CMC. We employ a dynamic thin film balance, to study the dynamics of freestanding films under both constant and time-varied pressure drops. We compare with the recently published results of Narayan et al. (2020) on colliding droplets of the same system with a hydrodynamic microfluidic trap, and show for the first time that agreement between the two lengthscales is possible, which indicates that the coalescence is indeed dominated by the dynamics in the film. We then address the scatter in the coalescence times and show that it can be affected by extrinsic factors, as well as by variations in the collision angle. Finally, we discuss the difficulties of extracting insight on the coalescence mechanism from coalescence time distributions when different effects such as impurities, small pressure variations, collision angle variations, and possible Marangoni-related instabilities are at play.",

keywords = "Coalescence, Drainage, Film dynamics, Marangoni, Surfactant",

author = "Emmanouil Chatzigiannakis and Yun Chen and Bachnak, \{Rana B\} and Dutcher, \{Cari S.\} and Jan Vermant",

note = "Funding Information: EC and JV would like to thank the ETH Energy Science Center Partnership with Shell for the financial support. CSD would like to acknowledge that this material is based upon work supported by the Humphreys Engineer Center Support Activity under Contracts No. W912HQ20C0041, corresponding to DOD Strategic Environmental Research and Development Program (SERDP) projects WP19-1407. The DOD SERDP support includes support for YC. CSD would also like to acknowledge support by Donaldson Company, including support for RB. Publisher Copyright: {\textcopyright} 2022, The Author(s).",

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AU - Dutcher, Cari S.

AU - Vermant, Jan

N1 - Funding Information: EC and JV would like to thank the ETH Energy Science Center Partnership with Shell for the financial support. CSD would like to acknowledge that this material is based upon work supported by the Humphreys Engineer Center Support Activity under Contracts No. W912HQ20C0041, corresponding to DOD Strategic Environmental Research and Development Program (SERDP) projects WP19-1407. The DOD SERDP support includes support for YC. CSD would also like to acknowledge support by Donaldson Company, including support for RB. Publisher Copyright: © 2022, The Author(s).

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N2 - The hydrodynamics of thin films is an important factor when it comes to the stability and rheology of multiphasic materials, such as foams, emulsions, and polymer blends. However, there have so far been only limited experimental studies addressing the dynamics of individual free-standing thin films at conditions similar to those encountered on macroscopic scales. In this article, we study a well-characterized system of a water-in-oil emulsion stabilized by a non-ionic surfactant (SPAN80) close to its CMC. We employ a dynamic thin film balance, to study the dynamics of freestanding films under both constant and time-varied pressure drops. We compare with the recently published results of Narayan et al. (2020) on colliding droplets of the same system with a hydrodynamic microfluidic trap, and show for the first time that agreement between the two lengthscales is possible, which indicates that the coalescence is indeed dominated by the dynamics in the film. We then address the scatter in the coalescence times and show that it can be affected by extrinsic factors, as well as by variations in the collision angle. Finally, we discuss the difficulties of extracting insight on the coalescence mechanism from coalescence time distributions when different effects such as impurities, small pressure variations, collision angle variations, and possible Marangoni-related instabilities are at play.

AB - The hydrodynamics of thin films is an important factor when it comes to the stability and rheology of multiphasic materials, such as foams, emulsions, and polymer blends. However, there have so far been only limited experimental studies addressing the dynamics of individual free-standing thin films at conditions similar to those encountered on macroscopic scales. In this article, we study a well-characterized system of a water-in-oil emulsion stabilized by a non-ionic surfactant (SPAN80) close to its CMC. We employ a dynamic thin film balance, to study the dynamics of freestanding films under both constant and time-varied pressure drops. We compare with the recently published results of Narayan et al. (2020) on colliding droplets of the same system with a hydrodynamic microfluidic trap, and show for the first time that agreement between the two lengthscales is possible, which indicates that the coalescence is indeed dominated by the dynamics in the film. We then address the scatter in the coalescence times and show that it can be affected by extrinsic factors, as well as by variations in the collision angle. Finally, we discuss the difficulties of extracting insight on the coalescence mechanism from coalescence time distributions when different effects such as impurities, small pressure variations, collision angle variations, and possible Marangoni-related instabilities are at play.

KW - Coalescence

KW - Drainage

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KW - Marangoni

KW - Surfactant

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ER -

Studying coalescence at different lengthscales: from films to droplets

Abstract

Bibliographical note

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